If $a_{n+2}=\frac {a_{n+1}+a_{n}}{2}$ $\forall n$>0 ,I have to show that $a_{n}\to \frac {a_{1}+2a_{2}}{3}$.
I don't know this problem is easy or difficult as intially I was posting here my query about question but at the time of writting problem I got this solution .If any mistake please tell me ..
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Curious student
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Also: https://math.stackexchange.com/q/1039868/42969, https://math.stackexchange.com/q/1472784/42969, https://math.stackexchange.com/q/859005/42969, https://math.stackexchange.com/q/1702193/42969. – Martin R May 04 '18 at 07:20
6 Answers
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Write $b=(a_1+2a_2)/3$ and $c=a_1-b$. Then $a_2-b=(-1/2)c$, $a_3-b=(1/4)c$ and in general $a_n-b=(-1/2)^{n-1}c$. So $a_n\to b$.
Angina Seng
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Nice answer But Sir is there in short method other than mentioned to find limit also because here you are assuming that is limit and then showing convergence. i.e what if we do not know Limit ? – Curious student May 04 '18 at 06:30
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If you consider $$a_{n+2}=\frac {a_{n+1}+a_{n}}{2}$$ the characteristic equation is $r^2=\frac{r+1}2$, the roots of which being $r_1=-\frac 12$ and $r_2=1$. So, the genaral solution is $$a_n=c_1 \left(-\frac{1}{2}\right)^n+c_2$$ If we impose $a_1=A$, $a_2=B$, this leads to
$$a_n=\frac 13 \left(A+2B+(-1)^n\frac{(B-A)}{2^{n-2}} \right)$$
Claude Leibovici
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Sir ,What is this characteristics equation ? can you explain something please? – Curious student May 04 '18 at 07:17
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First of all to show existence of limit We have term $a_1,a_2$ we know that given seunce is of artihematice mean or we also show that min{$a_1,a_2$}
< a3 < max{$a_1,a_2$}
WLOG say $a_1 < a_3 < a_2$
Similarly to above we can say that $a_3 < a_4 < a_2$ And by induction we can easily show that given sequence is monotonic and bounded above so Must be convergent to say a.
$a_{n+2}-a_{n+1}$=$\frac {a_{n}-a_{n+1}}{2}$
Taking Sum for index n we get as this alternating series
$\sum_{i=1}^n a_{i+2}-a_{+1}$=$\sum_{i=1}^n\frac {a_{i}-a_{i+1}}{2}$
So we left with $a_{n+2}-a_{2}$=$\frac {a_{1}-a_{n+1}}{2}$ By Transferring We left with what is needed $a_{n+2}-a_{n+1}/2$=$\frac {a_{1}+2a_{2}}{2}$
As $a_n \to a$ So 3$a_n$/2=$\frac {a_{1}+2a_{2}}{2}$ Which leads to required solution.
Curious student
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The characteristic equation: $2\lambda^2-\lambda -1=0$ has 2 solutions: $1$ and $\frac{-1}{2}.$
Thus, $a_{n}=A+B.\left(\frac{-1}{2}\right)^n,$ where $A$ and $B$ are constants such that $a_1=A-\frac{B}{2}, a_2=A+\frac{B}{4}.$ So, $A=\frac{a_1+2a_2}{3}.$
Moreover, $\{a_n\}$ converges to $A=\frac{a_1+2a_2}{3}.$
trancelocation
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Chanh Le Van
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Observe that
$$a_{n+1}-a_n=\frac{a_n-a_{n-1}}{-2}$$ and by induction
$$a_{n+1}-a_n=\frac{a_2-a_1}{(-2)^{n-1}}.$$
Then
$$a_{n}-a_1=(a_{n}-a_{n-1})+(a_{n-1}-a_{n-2})+\cdots(a_2-a_1)\\ =(a_2-a_1)\left(1-\frac12+\frac14-\cdots\frac1{(-2)^{n-2}}\right)$$
where the summation tends to $\dfrac23$. You can draw $a_\infty$.
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Let $a_1=a_2=1$. The next terms are obviously $1,1,1,\cdots$.
Now let $a_1=2,a_2=-1$. The next terms are $\frac12,-\frac14,\frac18,\cdots \left(-\frac12\right)^k,\cdots$ (because $\frac{\left(-\frac12\right)^0+\left(-\frac12\right)^1}2=\left(-\frac12\right)^2$).
Now for arbitrary $a_1,a_2$, find the linear combination such that
$$p\,(1,1)+q\,(2,-1)=(a_1,a_2).$$
From the linear system, $3p=a_1+2a_2$ and the limit is $1\,p+0\,q$.