Induction Proof for Sequences Announcing the arrival of Valued Associate #679: Cesar Manara Planned maintenance scheduled April 23, 2019 at 23:30 UTC (7:30pm US/Eastern)Find an explicit formula for the recursive sequenceGeneral formula for iterated cumulative sumUpper Bounds ProofShow That a Sequence is Monotonically IncreasingIs there a generalized analogue to the summation and product operators?How to prove this statement with “first” principle of Mathematical induction and not strong Mathematical induction?Sum of infinite series $sum_i=1^infty frac 1 i(i+1)(i+2)…(i+n)$Proof by induction of $s_k=2s_k-2$Sum of last digits of a sumProof by Induction: Recursively Defined Sequential Set
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Induction Proof for Sequences
Announcing the arrival of Valued Associate #679: Cesar Manara
Planned maintenance scheduled April 23, 2019 at 23:30 UTC (7:30pm US/Eastern)Find an explicit formula for the recursive sequenceGeneral formula for iterated cumulative sumUpper Bounds ProofShow That a Sequence is Monotonically IncreasingIs there a generalized analogue to the summation and product operators?How to prove this statement with “first” principle of Mathematical induction and not strong Mathematical induction?Sum of infinite series $sum_i=1^infty frac 1 i(i+1)(i+2)…(i+n)$Proof by induction of $s_k=2s_k-2$Sum of last digits of a sumProof by Induction: Recursively Defined Sequential Set
$begingroup$
Given a sequence $s_k=s_k-1+6k$, where $s_0=7$.
Question: First, find the closed formula for the $n$-th component of this sequence by hand and then prove that your formula is correct
My attempt:
I found the first couple of terms of the sequence to be
$s_0=7$,
$s_1=13$,
$s_2=25$,
$s_3=43$,
$s_4=67$ and
$s_5=97$.
I found the formula for the $n$-th term to be $s_n=3n^2+3n+7$.
Proof:
Base case $s_0=7$ therefore
$7=3cdot(0)^2+3cdot(0)+7$ so the formula works for the $s_0$ element.
I'm not sure how to proceed from here but I believe the proof should be a proof by Strong Induction. Any help will be greatly appreciated.
sequences-and-series induction
edited Apr 19 at 18:31
Marian G.
38426
asked Apr 19 at 18:22
JuliaJulia
113
New contributor
Julia is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
$endgroup$
add a comment |
$begingroup$
Given a sequence $s_k=s_k-1+6k$, where $s_0=7$.
Question: First, find the closed formula for the $n$-th component of this sequence by hand and then prove that your formula is correct
My attempt:
I found the first couple of terms of the sequence to be
$s_0=7$,
$s_1=13$,
$s_2=25$,
$s_3=43$,
$s_4=67$ and
$s_5=97$.
I found the formula for the $n$-th term to be $s_n=3n^2+3n+7$.
Proof:
Base case $s_0=7$ therefore
$7=3cdot(0)^2+3cdot(0)+7$ so the formula works for the $s_0$ element.
I'm not sure how to proceed from here but I believe the proof should be a proof by Strong Induction. Any help will be greatly appreciated.
sequences-and-series induction
edited Apr 19 at 18:31
Marian G.
38426
asked Apr 19 at 18:22
JuliaJulia
113
New contributor
Julia is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
$endgroup$
add a comment |
$begingroup$
Given a sequence $s_k=s_k-1+6k$, where $s_0=7$.
Question: First, find the closed formula for the $n$-th component of this sequence by hand and then prove that your formula is correct
My attempt:
I found the first couple of terms of the sequence to be
$s_0=7$,
$s_1=13$,
$s_2=25$,
$s_3=43$,
$s_4=67$ and
$s_5=97$.
I found the formula for the $n$-th term to be $s_n=3n^2+3n+7$.
Proof:
Base case $s_0=7$ therefore
$7=3cdot(0)^2+3cdot(0)+7$ so the formula works for the $s_0$ element.
I'm not sure how to proceed from here but I believe the proof should be a proof by Strong Induction. Any help will be greatly appreciated.
sequences-and-series induction
edited Apr 19 at 18:31
Marian G.
38426
asked Apr 19 at 18:22
JuliaJulia
113
New contributor
Julia is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
$endgroup$
Given a sequence $s_k=s_k-1+6k$, where $s_0=7$.
Question: First, find the closed formula for the $n$-th component of this sequence by hand and then prove that your formula is correct
My attempt:
I found the first couple of terms of the sequence to be
$s_0=7$,
$s_1=13$,
$s_2=25$,
$s_3=43$,
$s_4=67$ and
$s_5=97$.
I found the formula for the $n$-th term to be $s_n=3n^2+3n+7$.
Proof:
Base case $s_0=7$ therefore
$7=3cdot(0)^2+3cdot(0)+7$ so the formula works for the $s_0$ element.
I'm not sure how to proceed from here but I believe the proof should be a proof by Strong Induction. Any help will be greatly appreciated.
sequences-and-series induction
sequences-and-series induction
edited Apr 19 at 18:31
Marian G.
38426
asked Apr 19 at 18:22
JuliaJulia
113
New contributor
Julia is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
edited Apr 19 at 18:31
Marian G.
38426
asked Apr 19 at 18:22
JuliaJulia
113
New contributor
Julia is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
edited Apr 19 at 18:31
Marian G.
38426
edited Apr 19 at 18:31
Marian G.
38426
edited Apr 19 at 18:31
Marian G.
38426
38426
asked Apr 19 at 18:22
JuliaJulia
113
New contributor
Julia is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
asked Apr 19 at 18:22
JuliaJulia
113
asked Apr 19 at 18:22
JuliaJulia
113
113
New contributor
Julia is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
New contributor
Julia is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
Julia is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.
add a comment |
add a comment |
3 Answers
3
active
oldest
votes
$begingroup$
You just apply the recurrence
to your induction hypothesis.
If
$s_n=3n^2+3n+7
$,
then,
since
$s_k=s_k-1+6k
$,
$beginarray\
s_n+1
&=s_n+6(n+1)\
&=3n^2+3n+7+6(n+1)\
&=3n^2+9n+13\
endarray
$
If your hypothesis is true,
then
$beginarray\
s_n+1
&=3(n+1)^2+3(n+1)+7\
&=3(n^2+2n+1)+3(n+1)+7\
&=3n^2+6n+3+3n+3+7\
&=3n^2+9n+13\
endarray
$
This matches the result
from the induction step,
so the induction hypothesis is proved.
answered Apr 19 at 18:49
marty cohenmarty cohen
76.1k549130
$endgroup$
add a comment |
$begingroup$
FYI, here is a way to determine what the closed formula is without having to determine it by hand. This is an extension of the answer given by szw1710. The given sequence is
$$s_k=s_k-1+6k tag1labeleq1$$
Summing both sides of eqrefeq1 from $1$ to $n$ gives that
$sum_k=1^ns_k = sum_k=1^ns_k-1 + sum_k=1^n6k$
$sum_k=1^n-1s_k + s_n = s_0 + sum_k=1^n-1s_k + 6fracn(n+1)2$
$s_n = 7 + 3n(n+1) = 3n^2 + 3n + 7$
As you can see, this technique can easily be used in any cases where you have $s_k = s_k-1 + f(k)$ and the sum of $f(k)$ up to $k = n$ can be fairly easily determined.
More generally, your question is a fairly simple example of Linear Recurrence Relations with Constant Coefficients. You can use a certain technique of a characteristic equation, as described in that link, to directly determine the solution of even considerably more complicated such equations.
answered Apr 19 at 20:22
John OmielanJohn Omielan
5,3042218
$endgroup$
add a comment |
$begingroup$
It seems to me that induction is not needed here. Fix $kinBbb N.$ A direct computation shows that $s_k-s_k-1=6k$ and $s_0=7.$ However, there is another problem: both induction, and my method show that if $s_k=3k^2+3k+7$, then $s_k=s_k-1+6k$. In fact, whe should prove the converse: if $s_k=s_k-1+6k$ and $s_0=7$, then $s_k=3k^2+3k+7$. I will look for some reasoning going in this direction.
Let $s_0=7$ and $s_k=s_k-1+6k.$ Define $t_k=s_k-3k^2-3k-7.$ Then $t_0=0$. It is easy to prove (by direct computation) that $t_k=t_k-1$, so $(t_k)$ is a constant (in fact, zero) sequence. Then $s_k=3k^2+3k+7.$
answered Apr 19 at 18:46
szw1710szw1710
6,5701223
$endgroup$
1
$begingroup$
My answer has one way to show what you're asking about, i.e., "if $s_k=s_k-1+6k$ and $s_0=7$, then $a_k=3k^2+3k+7$".
$endgroup$
– John Omielan
Apr 19 at 20:24
$begingroup$
Yes, of course. About such techniques one could read in the "Concrete mathematics" book by Graham, Knuth, Patashnik.
$endgroup$
– szw1710
Apr 19 at 20:30
add a comment |
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3 Answers
3
active
oldest
votes
3 Answers
3
active
oldest
votes
active
oldest
votes
active
oldest
votes
$begingroup$
You just apply the recurrence
to your induction hypothesis.
If
$s_n=3n^2+3n+7
$,
then,
since
$s_k=s_k-1+6k
$,
$beginarray\
s_n+1
&=s_n+6(n+1)\
&=3n^2+3n+7+6(n+1)\
&=3n^2+9n+13\
endarray
$
If your hypothesis is true,
then
$beginarray\
s_n+1
&=3(n+1)^2+3(n+1)+7\
&=3(n^2+2n+1)+3(n+1)+7\
&=3n^2+6n+3+3n+3+7\
&=3n^2+9n+13\
endarray
$
This matches the result
from the induction step,
so the induction hypothesis is proved.
answered Apr 19 at 18:49
marty cohenmarty cohen
76.1k549130
$endgroup$
add a comment |
$begingroup$
You just apply the recurrence
to your induction hypothesis.
If
$s_n=3n^2+3n+7
$,
then,
since
$s_k=s_k-1+6k
$,
$beginarray\
s_n+1
&=s_n+6(n+1)\
&=3n^2+3n+7+6(n+1)\
&=3n^2+9n+13\
endarray
$
If your hypothesis is true,
then
$beginarray\
s_n+1
&=3(n+1)^2+3(n+1)+7\
&=3(n^2+2n+1)+3(n+1)+7\
&=3n^2+6n+3+3n+3+7\
&=3n^2+9n+13\
endarray
$
This matches the result
from the induction step,
so the induction hypothesis is proved.
answered Apr 19 at 18:49
marty cohenmarty cohen
76.1k549130
$endgroup$
add a comment |
$begingroup$
You just apply the recurrence
to your induction hypothesis.
If
$s_n=3n^2+3n+7
$,
then,
since
$s_k=s_k-1+6k
$,
$beginarray\
s_n+1
&=s_n+6(n+1)\
&=3n^2+3n+7+6(n+1)\
&=3n^2+9n+13\
endarray
$
If your hypothesis is true,
then
$beginarray\
s_n+1
&=3(n+1)^2+3(n+1)+7\
&=3(n^2+2n+1)+3(n+1)+7\
&=3n^2+6n+3+3n+3+7\
&=3n^2+9n+13\
endarray
$
This matches the result
from the induction step,
so the induction hypothesis is proved.
answered Apr 19 at 18:49
marty cohenmarty cohen
76.1k549130
$endgroup$
You just apply the recurrence
to your induction hypothesis.
If
$s_n=3n^2+3n+7
$,
then,
since
$s_k=s_k-1+6k
$,
$beginarray\
s_n+1
&=s_n+6(n+1)\
&=3n^2+3n+7+6(n+1)\
&=3n^2+9n+13\
endarray
$
If your hypothesis is true,
then
$beginarray\
s_n+1
&=3(n+1)^2+3(n+1)+7\
&=3(n^2+2n+1)+3(n+1)+7\
&=3n^2+6n+3+3n+3+7\
&=3n^2+9n+13\
endarray
$
This matches the result
from the induction step,
so the induction hypothesis is proved.
answered Apr 19 at 18:49
marty cohenmarty cohen
76.1k549130
answered Apr 19 at 18:49
marty cohenmarty cohen
76.1k549130
answered Apr 19 at 18:49
marty cohenmarty cohen
76.1k549130
answered Apr 19 at 18:49
marty cohenmarty cohen
76.1k549130
76.1k549130
add a comment |
add a comment |
$begingroup$
FYI, here is a way to determine what the closed formula is without having to determine it by hand. This is an extension of the answer given by szw1710. The given sequence is
$$s_k=s_k-1+6k tag1labeleq1$$
Summing both sides of eqrefeq1 from $1$ to $n$ gives that
$sum_k=1^ns_k = sum_k=1^ns_k-1 + sum_k=1^n6k$
$sum_k=1^n-1s_k + s_n = s_0 + sum_k=1^n-1s_k + 6fracn(n+1)2$
$s_n = 7 + 3n(n+1) = 3n^2 + 3n + 7$
As you can see, this technique can easily be used in any cases where you have $s_k = s_k-1 + f(k)$ and the sum of $f(k)$ up to $k = n$ can be fairly easily determined.
More generally, your question is a fairly simple example of Linear Recurrence Relations with Constant Coefficients. You can use a certain technique of a characteristic equation, as described in that link, to directly determine the solution of even considerably more complicated such equations.
answered Apr 19 at 20:22
John OmielanJohn Omielan
5,3042218
$endgroup$
add a comment |
$begingroup$
FYI, here is a way to determine what the closed formula is without having to determine it by hand. This is an extension of the answer given by szw1710. The given sequence is
$$s_k=s_k-1+6k tag1labeleq1$$
Summing both sides of eqrefeq1 from $1$ to $n$ gives that
$sum_k=1^ns_k = sum_k=1^ns_k-1 + sum_k=1^n6k$
$sum_k=1^n-1s_k + s_n = s_0 + sum_k=1^n-1s_k + 6fracn(n+1)2$
$s_n = 7 + 3n(n+1) = 3n^2 + 3n + 7$
As you can see, this technique can easily be used in any cases where you have $s_k = s_k-1 + f(k)$ and the sum of $f(k)$ up to $k = n$ can be fairly easily determined.
More generally, your question is a fairly simple example of Linear Recurrence Relations with Constant Coefficients. You can use a certain technique of a characteristic equation, as described in that link, to directly determine the solution of even considerably more complicated such equations.
answered Apr 19 at 20:22
John OmielanJohn Omielan
5,3042218
$endgroup$
add a comment |
$begingroup$
FYI, here is a way to determine what the closed formula is without having to determine it by hand. This is an extension of the answer given by szw1710. The given sequence is
$$s_k=s_k-1+6k tag1labeleq1$$
Summing both sides of eqrefeq1 from $1$ to $n$ gives that
$sum_k=1^ns_k = sum_k=1^ns_k-1 + sum_k=1^n6k$
$sum_k=1^n-1s_k + s_n = s_0 + sum_k=1^n-1s_k + 6fracn(n+1)2$
$s_n = 7 + 3n(n+1) = 3n^2 + 3n + 7$
As you can see, this technique can easily be used in any cases where you have $s_k = s_k-1 + f(k)$ and the sum of $f(k)$ up to $k = n$ can be fairly easily determined.
More generally, your question is a fairly simple example of Linear Recurrence Relations with Constant Coefficients. You can use a certain technique of a characteristic equation, as described in that link, to directly determine the solution of even considerably more complicated such equations.
answered Apr 19 at 20:22
John OmielanJohn Omielan
5,3042218
$endgroup$
FYI, here is a way to determine what the closed formula is without having to determine it by hand. This is an extension of the answer given by szw1710. The given sequence is
$$s_k=s_k-1+6k tag1labeleq1$$
Summing both sides of eqrefeq1 from $1$ to $n$ gives that
$sum_k=1^ns_k = sum_k=1^ns_k-1 + sum_k=1^n6k$
$sum_k=1^n-1s_k + s_n = s_0 + sum_k=1^n-1s_k + 6fracn(n+1)2$
$s_n = 7 + 3n(n+1) = 3n^2 + 3n + 7$
As you can see, this technique can easily be used in any cases where you have $s_k = s_k-1 + f(k)$ and the sum of $f(k)$ up to $k = n$ can be fairly easily determined.
More generally, your question is a fairly simple example of Linear Recurrence Relations with Constant Coefficients. You can use a certain technique of a characteristic equation, as described in that link, to directly determine the solution of even considerably more complicated such equations.
answered Apr 19 at 20:22
John OmielanJohn Omielan
5,3042218
edited Apr 19 at 20:32
answered Apr 19 at 20:22
John OmielanJohn Omielan
5,3042218
answered Apr 19 at 20:22
John OmielanJohn Omielan
5,3042218
answered Apr 19 at 20:22
John OmielanJohn Omielan
5,3042218
5,3042218
add a comment |
add a comment |
$begingroup$
It seems to me that induction is not needed here. Fix $kinBbb N.$ A direct computation shows that $s_k-s_k-1=6k$ and $s_0=7.$ However, there is another problem: both induction, and my method show that if $s_k=3k^2+3k+7$, then $s_k=s_k-1+6k$. In fact, whe should prove the converse: if $s_k=s_k-1+6k$ and $s_0=7$, then $s_k=3k^2+3k+7$. I will look for some reasoning going in this direction.
Let $s_0=7$ and $s_k=s_k-1+6k.$ Define $t_k=s_k-3k^2-3k-7.$ Then $t_0=0$. It is easy to prove (by direct computation) that $t_k=t_k-1$, so $(t_k)$ is a constant (in fact, zero) sequence. Then $s_k=3k^2+3k+7.$
answered Apr 19 at 18:46
szw1710szw1710
6,5701223
$endgroup$
1
$begingroup$
My answer has one way to show what you're asking about, i.e., "if $s_k=s_k-1+6k$ and $s_0=7$, then $a_k=3k^2+3k+7$".
$endgroup$
– John Omielan
Apr 19 at 20:24
$begingroup$
Yes, of course. About such techniques one could read in the "Concrete mathematics" book by Graham, Knuth, Patashnik.
$endgroup$
– szw1710
Apr 19 at 20:30
add a comment |
$begingroup$
It seems to me that induction is not needed here. Fix $kinBbb N.$ A direct computation shows that $s_k-s_k-1=6k$ and $s_0=7.$ However, there is another problem: both induction, and my method show that if $s_k=3k^2+3k+7$, then $s_k=s_k-1+6k$. In fact, whe should prove the converse: if $s_k=s_k-1+6k$ and $s_0=7$, then $s_k=3k^2+3k+7$. I will look for some reasoning going in this direction.
Let $s_0=7$ and $s_k=s_k-1+6k.$ Define $t_k=s_k-3k^2-3k-7.$ Then $t_0=0$. It is easy to prove (by direct computation) that $t_k=t_k-1$, so $(t_k)$ is a constant (in fact, zero) sequence. Then $s_k=3k^2+3k+7.$
answered Apr 19 at 18:46
szw1710szw1710
6,5701223
$endgroup$
1
$begingroup$
My answer has one way to show what you're asking about, i.e., "if $s_k=s_k-1+6k$ and $s_0=7$, then $a_k=3k^2+3k+7$".
$endgroup$
– John Omielan
Apr 19 at 20:24
$begingroup$
Yes, of course. About such techniques one could read in the "Concrete mathematics" book by Graham, Knuth, Patashnik.
$endgroup$
– szw1710
Apr 19 at 20:30
add a comment |
$begingroup$
It seems to me that induction is not needed here. Fix $kinBbb N.$ A direct computation shows that $s_k-s_k-1=6k$ and $s_0=7.$ However, there is another problem: both induction, and my method show that if $s_k=3k^2+3k+7$, then $s_k=s_k-1+6k$. In fact, whe should prove the converse: if $s_k=s_k-1+6k$ and $s_0=7$, then $s_k=3k^2+3k+7$. I will look for some reasoning going in this direction.
Let $s_0=7$ and $s_k=s_k-1+6k.$ Define $t_k=s_k-3k^2-3k-7.$ Then $t_0=0$. It is easy to prove (by direct computation) that $t_k=t_k-1$, so $(t_k)$ is a constant (in fact, zero) sequence. Then $s_k=3k^2+3k+7.$
answered Apr 19 at 18:46
szw1710szw1710
6,5701223
$endgroup$
It seems to me that induction is not needed here. Fix $kinBbb N.$ A direct computation shows that $s_k-s_k-1=6k$ and $s_0=7.$ However, there is another problem: both induction, and my method show that if $s_k=3k^2+3k+7$, then $s_k=s_k-1+6k$. In fact, whe should prove the converse: if $s_k=s_k-1+6k$ and $s_0=7$, then $s_k=3k^2+3k+7$. I will look for some reasoning going in this direction.
Let $s_0=7$ and $s_k=s_k-1+6k.$ Define $t_k=s_k-3k^2-3k-7.$ Then $t_0=0$. It is easy to prove (by direct computation) that $t_k=t_k-1$, so $(t_k)$ is a constant (in fact, zero) sequence. Then $s_k=3k^2+3k+7.$
answered Apr 19 at 18:46
szw1710szw1710
6,5701223
edited Apr 19 at 20:35
answered Apr 19 at 18:46
szw1710szw1710
6,5701223
answered Apr 19 at 18:46
szw1710szw1710
6,5701223
answered Apr 19 at 18:46
szw1710szw1710
6,5701223
6,5701223
1
$begingroup$
My answer has one way to show what you're asking about, i.e., "if $s_k=s_k-1+6k$ and $s_0=7$, then $a_k=3k^2+3k+7$".
$endgroup$
– John Omielan
Apr 19 at 20:24
$begingroup$
Yes, of course. About such techniques one could read in the "Concrete mathematics" book by Graham, Knuth, Patashnik.
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– szw1710
Apr 19 at 20:30
add a comment |
1
$begingroup$
My answer has one way to show what you're asking about, i.e., "if $s_k=s_k-1+6k$ and $s_0=7$, then $a_k=3k^2+3k+7$".
$endgroup$
– John Omielan
Apr 19 at 20:24
$begingroup$
Yes, of course. About such techniques one could read in the "Concrete mathematics" book by Graham, Knuth, Patashnik.
$endgroup$
– szw1710
Apr 19 at 20:30
1
1
$begingroup$
My answer has one way to show what you're asking about, i.e., "if $s_k=s_k-1+6k$ and $s_0=7$, then $a_k=3k^2+3k+7$".
$endgroup$
– John Omielan
Apr 19 at 20:24
$begingroup$
My answer has one way to show what you're asking about, i.e., "if $s_k=s_k-1+6k$ and $s_0=7$, then $a_k=3k^2+3k+7$".
$endgroup$
– John Omielan
Apr 19 at 20:24
$begingroup$
Yes, of course. About such techniques one could read in the "Concrete mathematics" book by Graham, Knuth, Patashnik.
$endgroup$
– szw1710
Apr 19 at 20:30
$begingroup$
Yes, of course. About such techniques one could read in the "Concrete mathematics" book by Graham, Knuth, Patashnik.
$endgroup$
– szw1710
Apr 19 at 20:30
add a comment |
Julia is a new contributor. Be nice, and check out our Code of Conduct.
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