0
votes
0answers
19 views

Solving a recurrence relation with absolute values in it.

The recurrence relation is: Let $\{y_{j}\}_{j\in \mathbb{N}}$ be a sequence of integers and x a real number then define: $P_{1}(x):=y_{1}+(-1)^{1}|x-y_{1}|$ and the general j-step as ...
0
votes
0answers
17 views

Comparing Generalized Continued Fractions

Gosper lays out a method (under Approximations) for comparing regular (a.k.a simple) continued fractions which have all partial numerators set to 1. Continue comparing terms until they differ, then ...
1
vote
1answer
68 views

Fibonacci numbers $F_{n+3} + F_{n} = 2F_{n+2}$

Prove $F_{n+3} + F_{n} = 2F_{n+2}$ for any positive integer n. So What I did was this: fn+ fn+1 = fn+2 fn + fn+1 = fn+2 => fn+2 -fn+1 fn+1 + fn+2 = fn+3 then I subsituted into equation in ...
1
vote
2answers
29 views

Finding the inhomogeneous solution

$x_{n+2} = x_{n+1} + 20x_n + n^2 + 5^n \text{ with } x_0 = 0 \text{ and } x_1 = 0$ How would I find the inhomogeneous solution for this since the homogenous solution is 0 given initial conditions?
1
vote
2answers
45 views
0
votes
3answers
62 views

Are Pell solutions “unique”??

Given the Pell equation $$X^2-2Y^2=1$$ and two solutions $(x_j,2uv)$ and $(x_k,2ac)$, with $uv=ac$ and $\gcd(u,v)=\gcd(a,c)=1$ and $u>v$ and $c>a$. Can one prove that $(u,v)=(c,a)$, and hence ...
0
votes
0answers
40 views

Mathematical function alike to primes

Note: I'm currently in a low level algebra class and have very little knowledge of some of the more complex mathematical concepts. That being said, I can probably figure out anything I don't know ...
2
votes
1answer
70 views

Define a recursive sequence for the following formula f(n) = n(n+1)

Define a recursive sequence for the following formula f(n) = n(n+1). Preferably one only defined by previous $a_n$ terms, i.e., no 'n' terms. If possible that is. So for example the following ...
-1
votes
2answers
127 views

how to find nth term of different fibonacci series with golden ratio [duplicate]

what i know : if i want to find $Nth$ term of a fibonacci series like : 1 1 2 3 5 8 13 21 ....... then to find $6th$ term we use golden ratio ...
6
votes
2answers
114 views

$a_1=1,a_{n+1}=\frac{n}{a_n}+\frac{a_n}{n}$. Prove that for $n\ge4$, $\lfloor{a_n^2}\rfloor=n$

Define a sequence $\left\lbrace a_{n}\right\rbrace$ by $\displaystyle{a_{1} = 1\,,\ a_{n + 1} = {n \over a_n} + {a_n \over n}.\quad}$ Prove that for $n \geq 4,\,\,\left\lfloor ...
1
vote
4answers
2k views

how to find nth term in a fibonacci series or sum of a series of fibonacci numbers

A series is given as $1,6,7,13,20,33,.......$ and so on Find the sum of first 52 terms? what i know is The sum of the first n Fibonacci numbers is the [(n + 2)nd Fibonacci number - 1] . So the sum ...
9
votes
3answers
284 views

The integer $c_n$ in $(1+4\sqrt[3]2-4\sqrt[3]4)^n=a_n+b_n\sqrt[3]2+c_n\sqrt[3]4$

For non-negative integer $n$, write $$(1+4\sqrt[3]2-4\sqrt[3]4)^n=a_n+b_n\sqrt[3]2+c_n\sqrt[3]4$$ where $a_n,b_n,c_n$ are integers. For any non-negative integer $m$, prove or disprove ...
0
votes
0answers
88 views

Continued fraction of $\gamma+1$ using recursion

Number $\gamma,$ the Euler-Mascheroni constant, is defined as the value of $$\gamma = \lim_{n\to\infty} \sum_{k=1}^n \frac{1}{k} - \ln(n).$$ We know that $$\lim_{n\to\infty} ...
1
vote
1answer
104 views

$n$-Bit Strings Not Containing $010$

So, I am asked to consider the number of $n$-bit strings that don't contain $010$ by considering the following $m$-leading-zero cases for $m\geq 0$, where $m\in \mathbb{N}$: $1\cdots$ $01\cdots$ ...
0
votes
1answer
112 views

Paths Within a Lattice

So, I'm reading this proof: Lemma 4.2. The Schröder numbers $(r(n):n\geq0))$ satisfy $$r(n)=r(n-1)+\sum_{k=0}^{n-1}r(k)r(n-1-k)\text{ for }n\geq1,\text{ with } r(0)=1$$ Proof. The Schröder number ...
27
votes
2answers
964 views

Limit of recursive sequence $a_{n+1} = \frac{a_n}{1- \{a_n\}}$

Consider the following sequence: let $a_0>0$ be rational. Define $$a_{n+1}= \frac{a_n}{1-\{a_n\}},$$ where $\{a_n\}$ is the fractional part of $a_n$ (i.e. $\{a_n\} = a_n - \lfloor a_n\rfloor$). ...
3
votes
2answers
86 views

How prove this $ a_{n+3}=8a_{n+2}-8a_{n+1}+a_{n}$

Define the sequence of integers $\{a_{n}\}$ as: $$\begin{cases} a_{1}=33,a_{2}=49,a_{3}=177\\ a_{n+3}=8a_{n+2}-8a_{n+1}+a_{n} \end{cases}$$ show that $a_{n}$ is not divisible by $2013(=61\times 33)$. ...
1
vote
3answers
133 views

Using complete induction, prove that if $a_1=2$, $a_2=4$, and $a_{n+2}=5a_{n+1}-6a_n$, then $a_n=2^n$

Could anyone please explain to me how to do this problem by using the principle of complete induction? Thanks. :) Let $a_1=2$, $a_2=4$, and $a_{n+2}=5a_{n+1}-6a_n$ for all $n\geq 1$. Prove that ...
6
votes
2answers
425 views

Convergence/Divergence of a particular infinite nested radical

Is it known if the following infinite nested radical converges or diverges (for $n \in \mathbb N$)?: $$R(n) = \sqrt{n+\sqrt{(n+1)+\sqrt{(n+2)+ \cdots}}}$$ I recently became interested in these ...
1
vote
2answers
48 views

Finding the kth term of an iterated sequence

The sequence $x_0, x_1, \dots$ is defined through $x_0 =3, x_1 = 18$ and $x_{n+2} = 6x_{n+1}-9x_n$ for $n=0,1,2,\dots\;$. What is the smallest $k$ such that $x_k$ is divisible by $2013$?
6
votes
5answers
200 views

How can I find the value of $a^n+b^n$, given the value of $a+b$, $ab$, and $n$?

I have been given the value of $a+b$ , $ab$ and $n$. I've to calculate the value of $a^n+b^n$. How can I do it? I would like to find out a general solution. Because the value of $n$ , $a+b$ and $ab$ ...
13
votes
5answers
392 views

Alternate proof that for every natural number $n,\ \left\lfloor\left(\frac{7+\sqrt{37}}{2}\right)^n\right\rfloor$ is divisible by $3$

Original Problem: Prove that for every natural number $n$,$$\left\lfloor\left(\frac{7+\sqrt{37}}{2}\right)^n\right\rfloor$$ is divisible by $3$. I found the problem in the book Winning ...
8
votes
1answer
220 views

Möbius function from random number sequence

Consider some arbitrary number sequence like the decimal expansion of $\pi$ = {3, 1, 4, 1, 5, 9, 2}. Prepend the sequence with the number $1$ so that you get {1, 3, 1, 4, 1, 5, 9, 2}. Then plug it ...
1
vote
1answer
111 views

Power Variant of Fibonacci sequence

I was trying to simplify the following sequence, such that I can calculate the $n$th term in $\log n$ time. This can be done, if we can express the $n$th in terms of combinations of Fibonacci like ...
13
votes
1answer
201 views

Integer Sequence “sums of digits of squares”.

For all $n \in \mathbb{N}$ we define the function $\delta(n)=p$, where $p$ is sums of digits of $n^2$. For example if $n=17, \ n^2=289$, then $\delta(17)=2+8+9=19$. Let $a_k$ is a monotonically ...
6
votes
1answer
322 views

Proving or disproving $f(n)-f(n-1)\le n, \forall n \gt 1$, for a recursive function with floors.

The Olympiad-style question I was given was as follows: A function $f:\mathbb{N}\to\mathbb{N}$ is defined by $f(1)=1$ and for $n>1$, by: ...
6
votes
1answer
185 views

Line in a proof on p69 in Cassel's Local Fields

I'm trying to read the proof of LEMMA 6.1 (Nagell) Let $u_n$ be defined by $u_0=0$, $u_1=1$ and $u_n=u_{n-1}-2u_{n-2} \hspace{20pt} (n\geq 2)$. Then $u_n=\pm1$ only for $n=1,2,3, ...
5
votes
0answers
512 views

The Average Running Time Of Euclid Algorithm?

What is the average running time of Euclid Algorithm with respect to all possible input pairs $(m,n)$ such that $\gcd(m,n) = d$? It seems very hard to deduce from the recurrence $T(m,n) = T(n, m ...