A sequence that avoids both arithmetic and geometric progressions












54














Sequences that avoid arithmetic progressions have been studied, e.g., "Sequences Containing No 3-Term Arithmetic Progressions," Janusz Dybizbański, 2012, journal link.



I started to explore sequences that avoid both arithmetic and geometric progressions,
i.e., avoid $x, x+c, x+2c$ and avoid $y, c y, c^2 y$ anywhere in the sequence
(not necessarily consecutively).
Starting with $(1,2)$, one cannot extend with $3$ because $(1,2,3)$ forms an
arithemtical progression, and one cannot extend with $4$ because $(1,2,4)$ is a geometric
progression. But $(1,2,5)$ is fine.



Continuing in the same manner leads to the following "greedy" sequence:
$$1, 2, 5, 6, 12, 13, 15, 16, 32, 33, 35, 39, 40, 42, 56, 81, 84, 85, 88,$$
$$90, 93, 94, 108, 109, 113, 115, 116, 159, 189, 207, 208, 222, ldots$$



This sequence is not in the OEIS.
Here are a few questions:




Q1. What is its growth rate?






 
 
 
Avoiding3Terms




Q2. Does $sum_{i=1}^infty 1/s_i$ converge? (Where $s_i$ is the $i$-th term of the above
sequence.)



Q3. If it does, does it converge to e?
Update: No. The sum appears to be approximately $2.73 > e$, as per
@MichaelStocker and @Turambar.




That is wild numerical speculation. The first 457 terms (the extent
of the graph above) sum to 2.70261.




Addendum. 11Jul2014. Starting with $(0,1)$ rather than $(1,2)$ renders
a direct hit on OEIS A225571.








share|cite|improve this question




















  • 6




    Expanding on your numerical data I conclude that Q3 can be answered in the negative. 457th term is 17933 with sum of reciprocals : 2.702607644337383 1000th term is 66102 : 2.718058753659135 but alas, somewhere shortly after that the sum excedes e. 2000 253701 2.7259164358931023. 3000 442429 2.7287027640882804.
    – Michael Stocker
    Jul 7 '14 at 13:16








  • 3




    The answer to Q2 is definitely Yes, it converges, because even just avoiding arithmetic progressions leads to convergence. Converges to what constant is unclear.
    – Joseph O'Rourke
    Jul 9 '14 at 0:33






  • 2




    @JosephO'Rourke Really? I may be ignorant here so going out on a limb, but I don't think $a_n=nln n$ is in an arithmetic progression, but the sum of its reciprocals diverges.
    – John Molokach
    Mar 25 '16 at 2:46








  • 1




    @JohnMolokach In fact, when you look at the difference in terms in the OEIS sequence, it looks a lot like OEIS A006519, which is $O(nln(n))$. The sequence talked about in the question is a bit different, but I think asymptotically they'd be the same, meaning the sum of reciprocals diverges. And of course, this is just a heuristic, not a proof.
    – Turambar
    Apr 28 '16 at 17:52






  • 1




    On the other hand, after looking at it out to $i = 10,000$, the chart of the differences doesn't seem to be as similar to A006519 as I thought. Its peaks grow faster and have a more bell curve distribution around them instead of the recursive characteristics of A006519. At $i = 10,000$, $ln(s_i)/ln(i) = 1.679258559$ and generally growing, with the sum of reciprocals around $2.734896156$. So if the "power" keeps generally growing (and doesn't start dropping to 1 after some point), then the sum is below $2.736095249$.
    – Turambar
    May 10 '16 at 16:14


















54














Sequences that avoid arithmetic progressions have been studied, e.g., "Sequences Containing No 3-Term Arithmetic Progressions," Janusz Dybizbański, 2012, journal link.



I started to explore sequences that avoid both arithmetic and geometric progressions,
i.e., avoid $x, x+c, x+2c$ and avoid $y, c y, c^2 y$ anywhere in the sequence
(not necessarily consecutively).
Starting with $(1,2)$, one cannot extend with $3$ because $(1,2,3)$ forms an
arithemtical progression, and one cannot extend with $4$ because $(1,2,4)$ is a geometric
progression. But $(1,2,5)$ is fine.



Continuing in the same manner leads to the following "greedy" sequence:
$$1, 2, 5, 6, 12, 13, 15, 16, 32, 33, 35, 39, 40, 42, 56, 81, 84, 85, 88,$$
$$90, 93, 94, 108, 109, 113, 115, 116, 159, 189, 207, 208, 222, ldots$$



This sequence is not in the OEIS.
Here are a few questions:




Q1. What is its growth rate?






 
 
 
Avoiding3Terms




Q2. Does $sum_{i=1}^infty 1/s_i$ converge? (Where $s_i$ is the $i$-th term of the above
sequence.)



Q3. If it does, does it converge to e?
Update: No. The sum appears to be approximately $2.73 > e$, as per
@MichaelStocker and @Turambar.




That is wild numerical speculation. The first 457 terms (the extent
of the graph above) sum to 2.70261.




Addendum. 11Jul2014. Starting with $(0,1)$ rather than $(1,2)$ renders
a direct hit on OEIS A225571.








share|cite|improve this question




















  • 6




    Expanding on your numerical data I conclude that Q3 can be answered in the negative. 457th term is 17933 with sum of reciprocals : 2.702607644337383 1000th term is 66102 : 2.718058753659135 but alas, somewhere shortly after that the sum excedes e. 2000 253701 2.7259164358931023. 3000 442429 2.7287027640882804.
    – Michael Stocker
    Jul 7 '14 at 13:16








  • 3




    The answer to Q2 is definitely Yes, it converges, because even just avoiding arithmetic progressions leads to convergence. Converges to what constant is unclear.
    – Joseph O'Rourke
    Jul 9 '14 at 0:33






  • 2




    @JosephO'Rourke Really? I may be ignorant here so going out on a limb, but I don't think $a_n=nln n$ is in an arithmetic progression, but the sum of its reciprocals diverges.
    – John Molokach
    Mar 25 '16 at 2:46








  • 1




    @JohnMolokach In fact, when you look at the difference in terms in the OEIS sequence, it looks a lot like OEIS A006519, which is $O(nln(n))$. The sequence talked about in the question is a bit different, but I think asymptotically they'd be the same, meaning the sum of reciprocals diverges. And of course, this is just a heuristic, not a proof.
    – Turambar
    Apr 28 '16 at 17:52






  • 1




    On the other hand, after looking at it out to $i = 10,000$, the chart of the differences doesn't seem to be as similar to A006519 as I thought. Its peaks grow faster and have a more bell curve distribution around them instead of the recursive characteristics of A006519. At $i = 10,000$, $ln(s_i)/ln(i) = 1.679258559$ and generally growing, with the sum of reciprocals around $2.734896156$. So if the "power" keeps generally growing (and doesn't start dropping to 1 after some point), then the sum is below $2.736095249$.
    – Turambar
    May 10 '16 at 16:14
















54












54








54


17





Sequences that avoid arithmetic progressions have been studied, e.g., "Sequences Containing No 3-Term Arithmetic Progressions," Janusz Dybizbański, 2012, journal link.



I started to explore sequences that avoid both arithmetic and geometric progressions,
i.e., avoid $x, x+c, x+2c$ and avoid $y, c y, c^2 y$ anywhere in the sequence
(not necessarily consecutively).
Starting with $(1,2)$, one cannot extend with $3$ because $(1,2,3)$ forms an
arithemtical progression, and one cannot extend with $4$ because $(1,2,4)$ is a geometric
progression. But $(1,2,5)$ is fine.



Continuing in the same manner leads to the following "greedy" sequence:
$$1, 2, 5, 6, 12, 13, 15, 16, 32, 33, 35, 39, 40, 42, 56, 81, 84, 85, 88,$$
$$90, 93, 94, 108, 109, 113, 115, 116, 159, 189, 207, 208, 222, ldots$$



This sequence is not in the OEIS.
Here are a few questions:




Q1. What is its growth rate?






 
 
 
Avoiding3Terms




Q2. Does $sum_{i=1}^infty 1/s_i$ converge? (Where $s_i$ is the $i$-th term of the above
sequence.)



Q3. If it does, does it converge to e?
Update: No. The sum appears to be approximately $2.73 > e$, as per
@MichaelStocker and @Turambar.




That is wild numerical speculation. The first 457 terms (the extent
of the graph above) sum to 2.70261.




Addendum. 11Jul2014. Starting with $(0,1)$ rather than $(1,2)$ renders
a direct hit on OEIS A225571.








share|cite|improve this question















Sequences that avoid arithmetic progressions have been studied, e.g., "Sequences Containing No 3-Term Arithmetic Progressions," Janusz Dybizbański, 2012, journal link.



I started to explore sequences that avoid both arithmetic and geometric progressions,
i.e., avoid $x, x+c, x+2c$ and avoid $y, c y, c^2 y$ anywhere in the sequence
(not necessarily consecutively).
Starting with $(1,2)$, one cannot extend with $3$ because $(1,2,3)$ forms an
arithemtical progression, and one cannot extend with $4$ because $(1,2,4)$ is a geometric
progression. But $(1,2,5)$ is fine.



Continuing in the same manner leads to the following "greedy" sequence:
$$1, 2, 5, 6, 12, 13, 15, 16, 32, 33, 35, 39, 40, 42, 56, 81, 84, 85, 88,$$
$$90, 93, 94, 108, 109, 113, 115, 116, 159, 189, 207, 208, 222, ldots$$



This sequence is not in the OEIS.
Here are a few questions:




Q1. What is its growth rate?






 
 
 
Avoiding3Terms




Q2. Does $sum_{i=1}^infty 1/s_i$ converge? (Where $s_i$ is the $i$-th term of the above
sequence.)



Q3. If it does, does it converge to e?
Update: No. The sum appears to be approximately $2.73 > e$, as per
@MichaelStocker and @Turambar.




That is wild numerical speculation. The first 457 terms (the extent
of the graph above) sum to 2.70261.




Addendum. 11Jul2014. Starting with $(0,1)$ rather than $(1,2)$ renders
a direct hit on OEIS A225571.





sequences-and-series number-theory






share|cite|improve this question















share|cite|improve this question













share|cite|improve this question




share|cite|improve this question








edited yesterday







Joseph O'Rourke

















asked Jul 7 '14 at 12:02









Joseph O'RourkeJoseph O'Rourke

17.9k348107




17.9k348107








  • 6




    Expanding on your numerical data I conclude that Q3 can be answered in the negative. 457th term is 17933 with sum of reciprocals : 2.702607644337383 1000th term is 66102 : 2.718058753659135 but alas, somewhere shortly after that the sum excedes e. 2000 253701 2.7259164358931023. 3000 442429 2.7287027640882804.
    – Michael Stocker
    Jul 7 '14 at 13:16








  • 3




    The answer to Q2 is definitely Yes, it converges, because even just avoiding arithmetic progressions leads to convergence. Converges to what constant is unclear.
    – Joseph O'Rourke
    Jul 9 '14 at 0:33






  • 2




    @JosephO'Rourke Really? I may be ignorant here so going out on a limb, but I don't think $a_n=nln n$ is in an arithmetic progression, but the sum of its reciprocals diverges.
    – John Molokach
    Mar 25 '16 at 2:46








  • 1




    @JohnMolokach In fact, when you look at the difference in terms in the OEIS sequence, it looks a lot like OEIS A006519, which is $O(nln(n))$. The sequence talked about in the question is a bit different, but I think asymptotically they'd be the same, meaning the sum of reciprocals diverges. And of course, this is just a heuristic, not a proof.
    – Turambar
    Apr 28 '16 at 17:52






  • 1




    On the other hand, after looking at it out to $i = 10,000$, the chart of the differences doesn't seem to be as similar to A006519 as I thought. Its peaks grow faster and have a more bell curve distribution around them instead of the recursive characteristics of A006519. At $i = 10,000$, $ln(s_i)/ln(i) = 1.679258559$ and generally growing, with the sum of reciprocals around $2.734896156$. So if the "power" keeps generally growing (and doesn't start dropping to 1 after some point), then the sum is below $2.736095249$.
    – Turambar
    May 10 '16 at 16:14
















  • 6




    Expanding on your numerical data I conclude that Q3 can be answered in the negative. 457th term is 17933 with sum of reciprocals : 2.702607644337383 1000th term is 66102 : 2.718058753659135 but alas, somewhere shortly after that the sum excedes e. 2000 253701 2.7259164358931023. 3000 442429 2.7287027640882804.
    – Michael Stocker
    Jul 7 '14 at 13:16








  • 3




    The answer to Q2 is definitely Yes, it converges, because even just avoiding arithmetic progressions leads to convergence. Converges to what constant is unclear.
    – Joseph O'Rourke
    Jul 9 '14 at 0:33






  • 2




    @JosephO'Rourke Really? I may be ignorant here so going out on a limb, but I don't think $a_n=nln n$ is in an arithmetic progression, but the sum of its reciprocals diverges.
    – John Molokach
    Mar 25 '16 at 2:46








  • 1




    @JohnMolokach In fact, when you look at the difference in terms in the OEIS sequence, it looks a lot like OEIS A006519, which is $O(nln(n))$. The sequence talked about in the question is a bit different, but I think asymptotically they'd be the same, meaning the sum of reciprocals diverges. And of course, this is just a heuristic, not a proof.
    – Turambar
    Apr 28 '16 at 17:52






  • 1




    On the other hand, after looking at it out to $i = 10,000$, the chart of the differences doesn't seem to be as similar to A006519 as I thought. Its peaks grow faster and have a more bell curve distribution around them instead of the recursive characteristics of A006519. At $i = 10,000$, $ln(s_i)/ln(i) = 1.679258559$ and generally growing, with the sum of reciprocals around $2.734896156$. So if the "power" keeps generally growing (and doesn't start dropping to 1 after some point), then the sum is below $2.736095249$.
    – Turambar
    May 10 '16 at 16:14










6




6




Expanding on your numerical data I conclude that Q3 can be answered in the negative. 457th term is 17933 with sum of reciprocals : 2.702607644337383 1000th term is 66102 : 2.718058753659135 but alas, somewhere shortly after that the sum excedes e. 2000 253701 2.7259164358931023. 3000 442429 2.7287027640882804.
– Michael Stocker
Jul 7 '14 at 13:16






Expanding on your numerical data I conclude that Q3 can be answered in the negative. 457th term is 17933 with sum of reciprocals : 2.702607644337383 1000th term is 66102 : 2.718058753659135 but alas, somewhere shortly after that the sum excedes e. 2000 253701 2.7259164358931023. 3000 442429 2.7287027640882804.
– Michael Stocker
Jul 7 '14 at 13:16






3




3




The answer to Q2 is definitely Yes, it converges, because even just avoiding arithmetic progressions leads to convergence. Converges to what constant is unclear.
– Joseph O'Rourke
Jul 9 '14 at 0:33




The answer to Q2 is definitely Yes, it converges, because even just avoiding arithmetic progressions leads to convergence. Converges to what constant is unclear.
– Joseph O'Rourke
Jul 9 '14 at 0:33




2




2




@JosephO'Rourke Really? I may be ignorant here so going out on a limb, but I don't think $a_n=nln n$ is in an arithmetic progression, but the sum of its reciprocals diverges.
– John Molokach
Mar 25 '16 at 2:46






@JosephO'Rourke Really? I may be ignorant here so going out on a limb, but I don't think $a_n=nln n$ is in an arithmetic progression, but the sum of its reciprocals diverges.
– John Molokach
Mar 25 '16 at 2:46






1




1




@JohnMolokach In fact, when you look at the difference in terms in the OEIS sequence, it looks a lot like OEIS A006519, which is $O(nln(n))$. The sequence talked about in the question is a bit different, but I think asymptotically they'd be the same, meaning the sum of reciprocals diverges. And of course, this is just a heuristic, not a proof.
– Turambar
Apr 28 '16 at 17:52




@JohnMolokach In fact, when you look at the difference in terms in the OEIS sequence, it looks a lot like OEIS A006519, which is $O(nln(n))$. The sequence talked about in the question is a bit different, but I think asymptotically they'd be the same, meaning the sum of reciprocals diverges. And of course, this is just a heuristic, not a proof.
– Turambar
Apr 28 '16 at 17:52




1




1




On the other hand, after looking at it out to $i = 10,000$, the chart of the differences doesn't seem to be as similar to A006519 as I thought. Its peaks grow faster and have a more bell curve distribution around them instead of the recursive characteristics of A006519. At $i = 10,000$, $ln(s_i)/ln(i) = 1.679258559$ and generally growing, with the sum of reciprocals around $2.734896156$. So if the "power" keeps generally growing (and doesn't start dropping to 1 after some point), then the sum is below $2.736095249$.
– Turambar
May 10 '16 at 16:14






On the other hand, after looking at it out to $i = 10,000$, the chart of the differences doesn't seem to be as similar to A006519 as I thought. Its peaks grow faster and have a more bell curve distribution around them instead of the recursive characteristics of A006519. At $i = 10,000$, $ln(s_i)/ln(i) = 1.679258559$ and generally growing, with the sum of reciprocals around $2.734896156$. So if the "power" keeps generally growing (and doesn't start dropping to 1 after some point), then the sum is below $2.736095249$.
– Turambar
May 10 '16 at 16:14












2 Answers
2






active

oldest

votes


















3














$color{brown}{textbf{HINT}}$



Denote the target sequence ${F_3(n)}$ and let us try to estimate the probability $P(N)}$ that natural number belongs to ${F_3}.$



Suppose
$$F_3(1)=1,quad F_3(2)=2,quad P(1)=P(2)=P(5) = P(6) = 1,\ P(3)=P(4)=P(7)=P(8)=0,tag1$$
$$V(N)=sumlimits_{i=1}^{N}P(i),quad F_3(N) = left[V^{-1}(N)right].tag2$$



Let $P_a(N)$ is the probability that N does not belong to arithmetic progression and $P_g(N)$ is the similar probability for geometric progressions.



Suppose
$$P(N) = P_a(N)P_g(N)).tag3$$



$color{brown}{textbf{Arithmetic Probability estimation.}}$



Suppose
$$P_a(N)=prodlimits_{k=1}^{[N/2]}P_a(N,k),tag4$$
where $P_a(N,k)$ is the probability that arithmetic progression ${N-2k,N-k, N}$ does not exist for any $j.$
Suppose
$$P_a(N,k) = big(1-P(N-2k)big)big((1-P(N-k)big).tag5$$



$color{brown}{textbf{Geometric Probability estimation.}}$



Suppose
$$P_g(N)=prodlimits_{k=1}^{left[,sqrt Nn,right]}P_g(N,k),tag6$$
where $P_g(N,k)$ is the probability that geometric progression $left(dfrac{N}{k^2}, dfrac Nk, Nright}$ with the denominator $k$ does not exist for all $i,j.$



Taking in account that the geometric progression can exist only if $k^2,| N,$ suppose
$$P_g(N,k) = left(1-dfrac1{k^2}Pleft(dfrac{N}{k^2}right)right)left(1-Pleft(dfrac{N}{k}right)right).tag7$$



$color{brown}{textbf{Common model.}}$



Common model can be simplified to next one,
begin{cases}
P(N) = 1-prodlimits_{k=1}^{[N/2-1]}Big(1-big(1-P(N-2k)big)big(1-P(N-k)big)Big)\
timesprodlimits_{k=1}^{left[sqrt Nright]}left(1-left(1-dfrac1{k^2}Pleft(dfrac{N}{k^2}right)right)left(1-Pleft(dfrac{N}{k}right)right)right)\[4pt]
P(1)=P(2)=P(5) = P(6) = 1,quad P(3)=P(4)=P(7)=P(8)=0\
V(N)=sumlimits_{i=1}^{N}P(i),quad F_3(n) = left[V^{-1}(n)right].tag8
end{cases}



Looking the solution in the form of
$$left{begin{align}
&P(N)=P_v(N),quadtext{where}quad v=left[dfrac{N-1 mod 4}2right],\[4pt]
&P_0(N)=
begin{cases}
1,quadtext{if}quad N<9\
cN^{-s},quadtext{otherwise}
end{cases}\[4pt]
&P_1(N)=
begin{cases}
0,quadtext{if}quad N<9\
dN^{-t},quadtext{otherwise}
end{cases}
end{align}right.tag9$$



then
$$begin{cases}
&P_0(N) =1-&prodlimits_{k=1}^{[N/4-1]}Big(1-big(1-P_0(N-4k)big)big(1-P_1(N-2k)big)Big)\
&&timesBig(1-big(1-P_1(N-4k-2)big)big(1-P_0(N-2k-1)big)Big)\
&&timesprodlimits_{k=1}^{left[sqrt N/2right]-1}
left(1-left(1-dfrac1{(2k-1)^2}P_0left(dfrac{N}{(2k-1)^2}right)right)
left(1-P_1left(dfrac{N}{2k-1}right)right)right)\[4pt]
&&timesleft(1-left(1-dfrac1{4k^2}P_1left(dfrac{N}{4k^2}right)right)
left(1-P_0left(dfrac{N}{2k}right)right)right)\[4pt]
&P_1(N) = 1- &prodlimits_{k=1}^{[N/4-1]}Big(1-big(1-P_1(N-4k)big)big(1-P_0(N-2k)big)Big)\
&&Big(1-big(1-P_0(N-4k-2)big)big(1-P_1(N-2k-1)big)Big)\
&&timesprodlimits_{k=1}^{left[sqrt N/2right]-1}
left(1-left(1-dfrac1{(2k-1)^2}P_1left(dfrac{N}{(2k-1)^2}right)right)
left(1-P_0left(dfrac{N}{2k-1}right)right)right)\[4pt]
&&timesleft(1-left(1-dfrac1{4k^2}P_0left(dfrac{N}{4k^2}right)right)
left(1-P_1left(dfrac{N}{2k}right)right)right).
end{cases}tag{10}$$



Taking in account $(9),$ can be written
$$begin{cases}
&P_0(N) =1-&prodlimits_{k=[N/4-2]}^{[N/4-1]},c(N-2k-1)^{-s}prodlimits_{k=1}^{[N/4-3]}Big(1-big(1-c(N-4k)^{-s}big)big(1-d(N-2k)^{-t}big)Big)\
&&timesBig(1-big(1-d(N-4k-2)^{-t}big)big(1-c(N-2k-1)^{-s}big)Big)\
&&timesprodlimits_{k=1}^{left[sqrt N/2right]-1}
left(1-left(1-dfrac1{(2k-1)^2}cleft(dfrac{N}{(2k-1)^2}right)^{-s}right)
left(1-dleft(dfrac{N}{2k-1}right)^{-t}right)right)\[4pt]
&&timesleft(1-left(1-dfrac1{4k^2}dleft(dfrac{N}{4k^2}right)^{-t}right)
left(1-cleft(dfrac{N}{2k}right)^{-s}right)right)\[4pt]
&P_1(N) = 1- &prodlimits_{k=[N/4-2]}^{[N/4-1]},c(N-2k)^{-s}prodlimits_{k=1}^{[N/4-3]}Big(1-big(1-d(N-4k)^{-t}big)big(1-(N-2k)^{-s}big)Big)\
&&Big(1-big(1-(N-4k-2)^{-s}big)big(1-d(N-2k-1)^{-t}big)Big)\
&&timesprodlimits_{k=1}^{left[sqrt N/2right]-1}
left(1-left(1-dfrac1{(2k-1)^2}dleft(dfrac{N}{(2k-1)^2}right)^{-t}right)
left(1-cleft(dfrac{N}{2k-1}right)^{-s}right)right)\[4pt]
&&timesleft(1-left(1-dfrac1{4k^2}cleft(dfrac{N}{4k^2}right)^{-s}right)
left(1-dleft(dfrac{N}{2k}right)^{-t}right)right).
end{cases}tag{11}$$



Model $(11)$ should be checked theoretically and practically, but it gives the approach to the required estimations.



The next steps are estimation of parameters $$c,d,s,t$$ and using of obtained model.






share|cite|improve this answer























  • @Joseph O'Rourke Approximation can be changed, but parametrization is actual.
    – Yuri Negometyanov
    23 hours ago



















2





+100









Since both @awwalker and @mathworker21 mentioned Erdős' conjecture, and because
a paper discussing this conjecture was just published, I thought I would mention it:




Erdős Conjecture (1940s or 1950s). If $A subset mathbb{N}$
satisfies $sum_{n in A} frac{1}{n}= infty$, then
$A$ contains arbitrarily long arithmetic progressions.




In




  • Grochow, Joshua. "New applications of the polynomial method: The cap
    set conjecture and beyond." Bulletin of the American Mathematical
    Society
    , Vol.56, No.1, Jan. 2019,


he says:




"It remains open even to prove that a set $A$ satisfying the hypothesis contains $3$-term arithmetic progressions."







share|cite|improve this answer























    Your Answer





    StackExchange.ifUsing("editor", function () {
    return StackExchange.using("mathjaxEditing", function () {
    StackExchange.MarkdownEditor.creationCallbacks.add(function (editor, postfix) {
    StackExchange.mathjaxEditing.prepareWmdForMathJax(editor, postfix, [["$", "$"], ["\\(","\\)"]]);
    });
    });
    }, "mathjax-editing");

    StackExchange.ready(function() {
    var channelOptions = {
    tags: "".split(" "),
    id: "69"
    };
    initTagRenderer("".split(" "), "".split(" "), channelOptions);

    StackExchange.using("externalEditor", function() {
    // Have to fire editor after snippets, if snippets enabled
    if (StackExchange.settings.snippets.snippetsEnabled) {
    StackExchange.using("snippets", function() {
    createEditor();
    });
    }
    else {
    createEditor();
    }
    });

    function createEditor() {
    StackExchange.prepareEditor({
    heartbeatType: 'answer',
    autoActivateHeartbeat: false,
    convertImagesToLinks: true,
    noModals: true,
    showLowRepImageUploadWarning: true,
    reputationToPostImages: 10,
    bindNavPrevention: true,
    postfix: "",
    imageUploader: {
    brandingHtml: "Powered by u003ca class="icon-imgur-white" href="https://imgur.com/"u003eu003c/au003e",
    contentPolicyHtml: "User contributions licensed under u003ca href="https://creativecommons.org/licenses/by-sa/3.0/"u003ecc by-sa 3.0 with attribution requiredu003c/au003e u003ca href="https://stackoverflow.com/legal/content-policy"u003e(content policy)u003c/au003e",
    allowUrls: true
    },
    noCode: true, onDemand: true,
    discardSelector: ".discard-answer"
    ,immediatelyShowMarkdownHelp:true
    });


    }
    });














    draft saved

    draft discarded


















    StackExchange.ready(
    function () {
    StackExchange.openid.initPostLogin('.new-post-login', 'https%3a%2f%2fmath.stackexchange.com%2fquestions%2f858918%2fa-sequence-that-avoids-both-arithmetic-and-geometric-progressions%23new-answer', 'question_page');
    }
    );

    Post as a guest















    Required, but never shown

























    2 Answers
    2






    active

    oldest

    votes








    2 Answers
    2






    active

    oldest

    votes









    active

    oldest

    votes






    active

    oldest

    votes









    3














    $color{brown}{textbf{HINT}}$



    Denote the target sequence ${F_3(n)}$ and let us try to estimate the probability $P(N)}$ that natural number belongs to ${F_3}.$



    Suppose
    $$F_3(1)=1,quad F_3(2)=2,quad P(1)=P(2)=P(5) = P(6) = 1,\ P(3)=P(4)=P(7)=P(8)=0,tag1$$
    $$V(N)=sumlimits_{i=1}^{N}P(i),quad F_3(N) = left[V^{-1}(N)right].tag2$$



    Let $P_a(N)$ is the probability that N does not belong to arithmetic progression and $P_g(N)$ is the similar probability for geometric progressions.



    Suppose
    $$P(N) = P_a(N)P_g(N)).tag3$$



    $color{brown}{textbf{Arithmetic Probability estimation.}}$



    Suppose
    $$P_a(N)=prodlimits_{k=1}^{[N/2]}P_a(N,k),tag4$$
    where $P_a(N,k)$ is the probability that arithmetic progression ${N-2k,N-k, N}$ does not exist for any $j.$
    Suppose
    $$P_a(N,k) = big(1-P(N-2k)big)big((1-P(N-k)big).tag5$$



    $color{brown}{textbf{Geometric Probability estimation.}}$



    Suppose
    $$P_g(N)=prodlimits_{k=1}^{left[,sqrt Nn,right]}P_g(N,k),tag6$$
    where $P_g(N,k)$ is the probability that geometric progression $left(dfrac{N}{k^2}, dfrac Nk, Nright}$ with the denominator $k$ does not exist for all $i,j.$



    Taking in account that the geometric progression can exist only if $k^2,| N,$ suppose
    $$P_g(N,k) = left(1-dfrac1{k^2}Pleft(dfrac{N}{k^2}right)right)left(1-Pleft(dfrac{N}{k}right)right).tag7$$



    $color{brown}{textbf{Common model.}}$



    Common model can be simplified to next one,
    begin{cases}
    P(N) = 1-prodlimits_{k=1}^{[N/2-1]}Big(1-big(1-P(N-2k)big)big(1-P(N-k)big)Big)\
    timesprodlimits_{k=1}^{left[sqrt Nright]}left(1-left(1-dfrac1{k^2}Pleft(dfrac{N}{k^2}right)right)left(1-Pleft(dfrac{N}{k}right)right)right)\[4pt]
    P(1)=P(2)=P(5) = P(6) = 1,quad P(3)=P(4)=P(7)=P(8)=0\
    V(N)=sumlimits_{i=1}^{N}P(i),quad F_3(n) = left[V^{-1}(n)right].tag8
    end{cases}



    Looking the solution in the form of
    $$left{begin{align}
    &P(N)=P_v(N),quadtext{where}quad v=left[dfrac{N-1 mod 4}2right],\[4pt]
    &P_0(N)=
    begin{cases}
    1,quadtext{if}quad N<9\
    cN^{-s},quadtext{otherwise}
    end{cases}\[4pt]
    &P_1(N)=
    begin{cases}
    0,quadtext{if}quad N<9\
    dN^{-t},quadtext{otherwise}
    end{cases}
    end{align}right.tag9$$



    then
    $$begin{cases}
    &P_0(N) =1-&prodlimits_{k=1}^{[N/4-1]}Big(1-big(1-P_0(N-4k)big)big(1-P_1(N-2k)big)Big)\
    &&timesBig(1-big(1-P_1(N-4k-2)big)big(1-P_0(N-2k-1)big)Big)\
    &&timesprodlimits_{k=1}^{left[sqrt N/2right]-1}
    left(1-left(1-dfrac1{(2k-1)^2}P_0left(dfrac{N}{(2k-1)^2}right)right)
    left(1-P_1left(dfrac{N}{2k-1}right)right)right)\[4pt]
    &&timesleft(1-left(1-dfrac1{4k^2}P_1left(dfrac{N}{4k^2}right)right)
    left(1-P_0left(dfrac{N}{2k}right)right)right)\[4pt]
    &P_1(N) = 1- &prodlimits_{k=1}^{[N/4-1]}Big(1-big(1-P_1(N-4k)big)big(1-P_0(N-2k)big)Big)\
    &&Big(1-big(1-P_0(N-4k-2)big)big(1-P_1(N-2k-1)big)Big)\
    &&timesprodlimits_{k=1}^{left[sqrt N/2right]-1}
    left(1-left(1-dfrac1{(2k-1)^2}P_1left(dfrac{N}{(2k-1)^2}right)right)
    left(1-P_0left(dfrac{N}{2k-1}right)right)right)\[4pt]
    &&timesleft(1-left(1-dfrac1{4k^2}P_0left(dfrac{N}{4k^2}right)right)
    left(1-P_1left(dfrac{N}{2k}right)right)right).
    end{cases}tag{10}$$



    Taking in account $(9),$ can be written
    $$begin{cases}
    &P_0(N) =1-&prodlimits_{k=[N/4-2]}^{[N/4-1]},c(N-2k-1)^{-s}prodlimits_{k=1}^{[N/4-3]}Big(1-big(1-c(N-4k)^{-s}big)big(1-d(N-2k)^{-t}big)Big)\
    &&timesBig(1-big(1-d(N-4k-2)^{-t}big)big(1-c(N-2k-1)^{-s}big)Big)\
    &&timesprodlimits_{k=1}^{left[sqrt N/2right]-1}
    left(1-left(1-dfrac1{(2k-1)^2}cleft(dfrac{N}{(2k-1)^2}right)^{-s}right)
    left(1-dleft(dfrac{N}{2k-1}right)^{-t}right)right)\[4pt]
    &&timesleft(1-left(1-dfrac1{4k^2}dleft(dfrac{N}{4k^2}right)^{-t}right)
    left(1-cleft(dfrac{N}{2k}right)^{-s}right)right)\[4pt]
    &P_1(N) = 1- &prodlimits_{k=[N/4-2]}^{[N/4-1]},c(N-2k)^{-s}prodlimits_{k=1}^{[N/4-3]}Big(1-big(1-d(N-4k)^{-t}big)big(1-(N-2k)^{-s}big)Big)\
    &&Big(1-big(1-(N-4k-2)^{-s}big)big(1-d(N-2k-1)^{-t}big)Big)\
    &&timesprodlimits_{k=1}^{left[sqrt N/2right]-1}
    left(1-left(1-dfrac1{(2k-1)^2}dleft(dfrac{N}{(2k-1)^2}right)^{-t}right)
    left(1-cleft(dfrac{N}{2k-1}right)^{-s}right)right)\[4pt]
    &&timesleft(1-left(1-dfrac1{4k^2}cleft(dfrac{N}{4k^2}right)^{-s}right)
    left(1-dleft(dfrac{N}{2k}right)^{-t}right)right).
    end{cases}tag{11}$$



    Model $(11)$ should be checked theoretically and practically, but it gives the approach to the required estimations.



    The next steps are estimation of parameters $$c,d,s,t$$ and using of obtained model.






    share|cite|improve this answer























    • @Joseph O'Rourke Approximation can be changed, but parametrization is actual.
      – Yuri Negometyanov
      23 hours ago
















    3














    $color{brown}{textbf{HINT}}$



    Denote the target sequence ${F_3(n)}$ and let us try to estimate the probability $P(N)}$ that natural number belongs to ${F_3}.$



    Suppose
    $$F_3(1)=1,quad F_3(2)=2,quad P(1)=P(2)=P(5) = P(6) = 1,\ P(3)=P(4)=P(7)=P(8)=0,tag1$$
    $$V(N)=sumlimits_{i=1}^{N}P(i),quad F_3(N) = left[V^{-1}(N)right].tag2$$



    Let $P_a(N)$ is the probability that N does not belong to arithmetic progression and $P_g(N)$ is the similar probability for geometric progressions.



    Suppose
    $$P(N) = P_a(N)P_g(N)).tag3$$



    $color{brown}{textbf{Arithmetic Probability estimation.}}$



    Suppose
    $$P_a(N)=prodlimits_{k=1}^{[N/2]}P_a(N,k),tag4$$
    where $P_a(N,k)$ is the probability that arithmetic progression ${N-2k,N-k, N}$ does not exist for any $j.$
    Suppose
    $$P_a(N,k) = big(1-P(N-2k)big)big((1-P(N-k)big).tag5$$



    $color{brown}{textbf{Geometric Probability estimation.}}$



    Suppose
    $$P_g(N)=prodlimits_{k=1}^{left[,sqrt Nn,right]}P_g(N,k),tag6$$
    where $P_g(N,k)$ is the probability that geometric progression $left(dfrac{N}{k^2}, dfrac Nk, Nright}$ with the denominator $k$ does not exist for all $i,j.$



    Taking in account that the geometric progression can exist only if $k^2,| N,$ suppose
    $$P_g(N,k) = left(1-dfrac1{k^2}Pleft(dfrac{N}{k^2}right)right)left(1-Pleft(dfrac{N}{k}right)right).tag7$$



    $color{brown}{textbf{Common model.}}$



    Common model can be simplified to next one,
    begin{cases}
    P(N) = 1-prodlimits_{k=1}^{[N/2-1]}Big(1-big(1-P(N-2k)big)big(1-P(N-k)big)Big)\
    timesprodlimits_{k=1}^{left[sqrt Nright]}left(1-left(1-dfrac1{k^2}Pleft(dfrac{N}{k^2}right)right)left(1-Pleft(dfrac{N}{k}right)right)right)\[4pt]
    P(1)=P(2)=P(5) = P(6) = 1,quad P(3)=P(4)=P(7)=P(8)=0\
    V(N)=sumlimits_{i=1}^{N}P(i),quad F_3(n) = left[V^{-1}(n)right].tag8
    end{cases}



    Looking the solution in the form of
    $$left{begin{align}
    &P(N)=P_v(N),quadtext{where}quad v=left[dfrac{N-1 mod 4}2right],\[4pt]
    &P_0(N)=
    begin{cases}
    1,quadtext{if}quad N<9\
    cN^{-s},quadtext{otherwise}
    end{cases}\[4pt]
    &P_1(N)=
    begin{cases}
    0,quadtext{if}quad N<9\
    dN^{-t},quadtext{otherwise}
    end{cases}
    end{align}right.tag9$$



    then
    $$begin{cases}
    &P_0(N) =1-&prodlimits_{k=1}^{[N/4-1]}Big(1-big(1-P_0(N-4k)big)big(1-P_1(N-2k)big)Big)\
    &&timesBig(1-big(1-P_1(N-4k-2)big)big(1-P_0(N-2k-1)big)Big)\
    &&timesprodlimits_{k=1}^{left[sqrt N/2right]-1}
    left(1-left(1-dfrac1{(2k-1)^2}P_0left(dfrac{N}{(2k-1)^2}right)right)
    left(1-P_1left(dfrac{N}{2k-1}right)right)right)\[4pt]
    &&timesleft(1-left(1-dfrac1{4k^2}P_1left(dfrac{N}{4k^2}right)right)
    left(1-P_0left(dfrac{N}{2k}right)right)right)\[4pt]
    &P_1(N) = 1- &prodlimits_{k=1}^{[N/4-1]}Big(1-big(1-P_1(N-4k)big)big(1-P_0(N-2k)big)Big)\
    &&Big(1-big(1-P_0(N-4k-2)big)big(1-P_1(N-2k-1)big)Big)\
    &&timesprodlimits_{k=1}^{left[sqrt N/2right]-1}
    left(1-left(1-dfrac1{(2k-1)^2}P_1left(dfrac{N}{(2k-1)^2}right)right)
    left(1-P_0left(dfrac{N}{2k-1}right)right)right)\[4pt]
    &&timesleft(1-left(1-dfrac1{4k^2}P_0left(dfrac{N}{4k^2}right)right)
    left(1-P_1left(dfrac{N}{2k}right)right)right).
    end{cases}tag{10}$$



    Taking in account $(9),$ can be written
    $$begin{cases}
    &P_0(N) =1-&prodlimits_{k=[N/4-2]}^{[N/4-1]},c(N-2k-1)^{-s}prodlimits_{k=1}^{[N/4-3]}Big(1-big(1-c(N-4k)^{-s}big)big(1-d(N-2k)^{-t}big)Big)\
    &&timesBig(1-big(1-d(N-4k-2)^{-t}big)big(1-c(N-2k-1)^{-s}big)Big)\
    &&timesprodlimits_{k=1}^{left[sqrt N/2right]-1}
    left(1-left(1-dfrac1{(2k-1)^2}cleft(dfrac{N}{(2k-1)^2}right)^{-s}right)
    left(1-dleft(dfrac{N}{2k-1}right)^{-t}right)right)\[4pt]
    &&timesleft(1-left(1-dfrac1{4k^2}dleft(dfrac{N}{4k^2}right)^{-t}right)
    left(1-cleft(dfrac{N}{2k}right)^{-s}right)right)\[4pt]
    &P_1(N) = 1- &prodlimits_{k=[N/4-2]}^{[N/4-1]},c(N-2k)^{-s}prodlimits_{k=1}^{[N/4-3]}Big(1-big(1-d(N-4k)^{-t}big)big(1-(N-2k)^{-s}big)Big)\
    &&Big(1-big(1-(N-4k-2)^{-s}big)big(1-d(N-2k-1)^{-t}big)Big)\
    &&timesprodlimits_{k=1}^{left[sqrt N/2right]-1}
    left(1-left(1-dfrac1{(2k-1)^2}dleft(dfrac{N}{(2k-1)^2}right)^{-t}right)
    left(1-cleft(dfrac{N}{2k-1}right)^{-s}right)right)\[4pt]
    &&timesleft(1-left(1-dfrac1{4k^2}cleft(dfrac{N}{4k^2}right)^{-s}right)
    left(1-dleft(dfrac{N}{2k}right)^{-t}right)right).
    end{cases}tag{11}$$



    Model $(11)$ should be checked theoretically and practically, but it gives the approach to the required estimations.



    The next steps are estimation of parameters $$c,d,s,t$$ and using of obtained model.






    share|cite|improve this answer























    • @Joseph O'Rourke Approximation can be changed, but parametrization is actual.
      – Yuri Negometyanov
      23 hours ago














    3












    3








    3






    $color{brown}{textbf{HINT}}$



    Denote the target sequence ${F_3(n)}$ and let us try to estimate the probability $P(N)}$ that natural number belongs to ${F_3}.$



    Suppose
    $$F_3(1)=1,quad F_3(2)=2,quad P(1)=P(2)=P(5) = P(6) = 1,\ P(3)=P(4)=P(7)=P(8)=0,tag1$$
    $$V(N)=sumlimits_{i=1}^{N}P(i),quad F_3(N) = left[V^{-1}(N)right].tag2$$



    Let $P_a(N)$ is the probability that N does not belong to arithmetic progression and $P_g(N)$ is the similar probability for geometric progressions.



    Suppose
    $$P(N) = P_a(N)P_g(N)).tag3$$



    $color{brown}{textbf{Arithmetic Probability estimation.}}$



    Suppose
    $$P_a(N)=prodlimits_{k=1}^{[N/2]}P_a(N,k),tag4$$
    where $P_a(N,k)$ is the probability that arithmetic progression ${N-2k,N-k, N}$ does not exist for any $j.$
    Suppose
    $$P_a(N,k) = big(1-P(N-2k)big)big((1-P(N-k)big).tag5$$



    $color{brown}{textbf{Geometric Probability estimation.}}$



    Suppose
    $$P_g(N)=prodlimits_{k=1}^{left[,sqrt Nn,right]}P_g(N,k),tag6$$
    where $P_g(N,k)$ is the probability that geometric progression $left(dfrac{N}{k^2}, dfrac Nk, Nright}$ with the denominator $k$ does not exist for all $i,j.$



    Taking in account that the geometric progression can exist only if $k^2,| N,$ suppose
    $$P_g(N,k) = left(1-dfrac1{k^2}Pleft(dfrac{N}{k^2}right)right)left(1-Pleft(dfrac{N}{k}right)right).tag7$$



    $color{brown}{textbf{Common model.}}$



    Common model can be simplified to next one,
    begin{cases}
    P(N) = 1-prodlimits_{k=1}^{[N/2-1]}Big(1-big(1-P(N-2k)big)big(1-P(N-k)big)Big)\
    timesprodlimits_{k=1}^{left[sqrt Nright]}left(1-left(1-dfrac1{k^2}Pleft(dfrac{N}{k^2}right)right)left(1-Pleft(dfrac{N}{k}right)right)right)\[4pt]
    P(1)=P(2)=P(5) = P(6) = 1,quad P(3)=P(4)=P(7)=P(8)=0\
    V(N)=sumlimits_{i=1}^{N}P(i),quad F_3(n) = left[V^{-1}(n)right].tag8
    end{cases}



    Looking the solution in the form of
    $$left{begin{align}
    &P(N)=P_v(N),quadtext{where}quad v=left[dfrac{N-1 mod 4}2right],\[4pt]
    &P_0(N)=
    begin{cases}
    1,quadtext{if}quad N<9\
    cN^{-s},quadtext{otherwise}
    end{cases}\[4pt]
    &P_1(N)=
    begin{cases}
    0,quadtext{if}quad N<9\
    dN^{-t},quadtext{otherwise}
    end{cases}
    end{align}right.tag9$$



    then
    $$begin{cases}
    &P_0(N) =1-&prodlimits_{k=1}^{[N/4-1]}Big(1-big(1-P_0(N-4k)big)big(1-P_1(N-2k)big)Big)\
    &&timesBig(1-big(1-P_1(N-4k-2)big)big(1-P_0(N-2k-1)big)Big)\
    &&timesprodlimits_{k=1}^{left[sqrt N/2right]-1}
    left(1-left(1-dfrac1{(2k-1)^2}P_0left(dfrac{N}{(2k-1)^2}right)right)
    left(1-P_1left(dfrac{N}{2k-1}right)right)right)\[4pt]
    &&timesleft(1-left(1-dfrac1{4k^2}P_1left(dfrac{N}{4k^2}right)right)
    left(1-P_0left(dfrac{N}{2k}right)right)right)\[4pt]
    &P_1(N) = 1- &prodlimits_{k=1}^{[N/4-1]}Big(1-big(1-P_1(N-4k)big)big(1-P_0(N-2k)big)Big)\
    &&Big(1-big(1-P_0(N-4k-2)big)big(1-P_1(N-2k-1)big)Big)\
    &&timesprodlimits_{k=1}^{left[sqrt N/2right]-1}
    left(1-left(1-dfrac1{(2k-1)^2}P_1left(dfrac{N}{(2k-1)^2}right)right)
    left(1-P_0left(dfrac{N}{2k-1}right)right)right)\[4pt]
    &&timesleft(1-left(1-dfrac1{4k^2}P_0left(dfrac{N}{4k^2}right)right)
    left(1-P_1left(dfrac{N}{2k}right)right)right).
    end{cases}tag{10}$$



    Taking in account $(9),$ can be written
    $$begin{cases}
    &P_0(N) =1-&prodlimits_{k=[N/4-2]}^{[N/4-1]},c(N-2k-1)^{-s}prodlimits_{k=1}^{[N/4-3]}Big(1-big(1-c(N-4k)^{-s}big)big(1-d(N-2k)^{-t}big)Big)\
    &&timesBig(1-big(1-d(N-4k-2)^{-t}big)big(1-c(N-2k-1)^{-s}big)Big)\
    &&timesprodlimits_{k=1}^{left[sqrt N/2right]-1}
    left(1-left(1-dfrac1{(2k-1)^2}cleft(dfrac{N}{(2k-1)^2}right)^{-s}right)
    left(1-dleft(dfrac{N}{2k-1}right)^{-t}right)right)\[4pt]
    &&timesleft(1-left(1-dfrac1{4k^2}dleft(dfrac{N}{4k^2}right)^{-t}right)
    left(1-cleft(dfrac{N}{2k}right)^{-s}right)right)\[4pt]
    &P_1(N) = 1- &prodlimits_{k=[N/4-2]}^{[N/4-1]},c(N-2k)^{-s}prodlimits_{k=1}^{[N/4-3]}Big(1-big(1-d(N-4k)^{-t}big)big(1-(N-2k)^{-s}big)Big)\
    &&Big(1-big(1-(N-4k-2)^{-s}big)big(1-d(N-2k-1)^{-t}big)Big)\
    &&timesprodlimits_{k=1}^{left[sqrt N/2right]-1}
    left(1-left(1-dfrac1{(2k-1)^2}dleft(dfrac{N}{(2k-1)^2}right)^{-t}right)
    left(1-cleft(dfrac{N}{2k-1}right)^{-s}right)right)\[4pt]
    &&timesleft(1-left(1-dfrac1{4k^2}cleft(dfrac{N}{4k^2}right)^{-s}right)
    left(1-dleft(dfrac{N}{2k}right)^{-t}right)right).
    end{cases}tag{11}$$



    Model $(11)$ should be checked theoretically and practically, but it gives the approach to the required estimations.



    The next steps are estimation of parameters $$c,d,s,t$$ and using of obtained model.






    share|cite|improve this answer














    $color{brown}{textbf{HINT}}$



    Denote the target sequence ${F_3(n)}$ and let us try to estimate the probability $P(N)}$ that natural number belongs to ${F_3}.$



    Suppose
    $$F_3(1)=1,quad F_3(2)=2,quad P(1)=P(2)=P(5) = P(6) = 1,\ P(3)=P(4)=P(7)=P(8)=0,tag1$$
    $$V(N)=sumlimits_{i=1}^{N}P(i),quad F_3(N) = left[V^{-1}(N)right].tag2$$



    Let $P_a(N)$ is the probability that N does not belong to arithmetic progression and $P_g(N)$ is the similar probability for geometric progressions.



    Suppose
    $$P(N) = P_a(N)P_g(N)).tag3$$



    $color{brown}{textbf{Arithmetic Probability estimation.}}$



    Suppose
    $$P_a(N)=prodlimits_{k=1}^{[N/2]}P_a(N,k),tag4$$
    where $P_a(N,k)$ is the probability that arithmetic progression ${N-2k,N-k, N}$ does not exist for any $j.$
    Suppose
    $$P_a(N,k) = big(1-P(N-2k)big)big((1-P(N-k)big).tag5$$



    $color{brown}{textbf{Geometric Probability estimation.}}$



    Suppose
    $$P_g(N)=prodlimits_{k=1}^{left[,sqrt Nn,right]}P_g(N,k),tag6$$
    where $P_g(N,k)$ is the probability that geometric progression $left(dfrac{N}{k^2}, dfrac Nk, Nright}$ with the denominator $k$ does not exist for all $i,j.$



    Taking in account that the geometric progression can exist only if $k^2,| N,$ suppose
    $$P_g(N,k) = left(1-dfrac1{k^2}Pleft(dfrac{N}{k^2}right)right)left(1-Pleft(dfrac{N}{k}right)right).tag7$$



    $color{brown}{textbf{Common model.}}$



    Common model can be simplified to next one,
    begin{cases}
    P(N) = 1-prodlimits_{k=1}^{[N/2-1]}Big(1-big(1-P(N-2k)big)big(1-P(N-k)big)Big)\
    timesprodlimits_{k=1}^{left[sqrt Nright]}left(1-left(1-dfrac1{k^2}Pleft(dfrac{N}{k^2}right)right)left(1-Pleft(dfrac{N}{k}right)right)right)\[4pt]
    P(1)=P(2)=P(5) = P(6) = 1,quad P(3)=P(4)=P(7)=P(8)=0\
    V(N)=sumlimits_{i=1}^{N}P(i),quad F_3(n) = left[V^{-1}(n)right].tag8
    end{cases}



    Looking the solution in the form of
    $$left{begin{align}
    &P(N)=P_v(N),quadtext{where}quad v=left[dfrac{N-1 mod 4}2right],\[4pt]
    &P_0(N)=
    begin{cases}
    1,quadtext{if}quad N<9\
    cN^{-s},quadtext{otherwise}
    end{cases}\[4pt]
    &P_1(N)=
    begin{cases}
    0,quadtext{if}quad N<9\
    dN^{-t},quadtext{otherwise}
    end{cases}
    end{align}right.tag9$$



    then
    $$begin{cases}
    &P_0(N) =1-&prodlimits_{k=1}^{[N/4-1]}Big(1-big(1-P_0(N-4k)big)big(1-P_1(N-2k)big)Big)\
    &&timesBig(1-big(1-P_1(N-4k-2)big)big(1-P_0(N-2k-1)big)Big)\
    &&timesprodlimits_{k=1}^{left[sqrt N/2right]-1}
    left(1-left(1-dfrac1{(2k-1)^2}P_0left(dfrac{N}{(2k-1)^2}right)right)
    left(1-P_1left(dfrac{N}{2k-1}right)right)right)\[4pt]
    &&timesleft(1-left(1-dfrac1{4k^2}P_1left(dfrac{N}{4k^2}right)right)
    left(1-P_0left(dfrac{N}{2k}right)right)right)\[4pt]
    &P_1(N) = 1- &prodlimits_{k=1}^{[N/4-1]}Big(1-big(1-P_1(N-4k)big)big(1-P_0(N-2k)big)Big)\
    &&Big(1-big(1-P_0(N-4k-2)big)big(1-P_1(N-2k-1)big)Big)\
    &&timesprodlimits_{k=1}^{left[sqrt N/2right]-1}
    left(1-left(1-dfrac1{(2k-1)^2}P_1left(dfrac{N}{(2k-1)^2}right)right)
    left(1-P_0left(dfrac{N}{2k-1}right)right)right)\[4pt]
    &&timesleft(1-left(1-dfrac1{4k^2}P_0left(dfrac{N}{4k^2}right)right)
    left(1-P_1left(dfrac{N}{2k}right)right)right).
    end{cases}tag{10}$$



    Taking in account $(9),$ can be written
    $$begin{cases}
    &P_0(N) =1-&prodlimits_{k=[N/4-2]}^{[N/4-1]},c(N-2k-1)^{-s}prodlimits_{k=1}^{[N/4-3]}Big(1-big(1-c(N-4k)^{-s}big)big(1-d(N-2k)^{-t}big)Big)\
    &&timesBig(1-big(1-d(N-4k-2)^{-t}big)big(1-c(N-2k-1)^{-s}big)Big)\
    &&timesprodlimits_{k=1}^{left[sqrt N/2right]-1}
    left(1-left(1-dfrac1{(2k-1)^2}cleft(dfrac{N}{(2k-1)^2}right)^{-s}right)
    left(1-dleft(dfrac{N}{2k-1}right)^{-t}right)right)\[4pt]
    &&timesleft(1-left(1-dfrac1{4k^2}dleft(dfrac{N}{4k^2}right)^{-t}right)
    left(1-cleft(dfrac{N}{2k}right)^{-s}right)right)\[4pt]
    &P_1(N) = 1- &prodlimits_{k=[N/4-2]}^{[N/4-1]},c(N-2k)^{-s}prodlimits_{k=1}^{[N/4-3]}Big(1-big(1-d(N-4k)^{-t}big)big(1-(N-2k)^{-s}big)Big)\
    &&Big(1-big(1-(N-4k-2)^{-s}big)big(1-d(N-2k-1)^{-t}big)Big)\
    &&timesprodlimits_{k=1}^{left[sqrt N/2right]-1}
    left(1-left(1-dfrac1{(2k-1)^2}dleft(dfrac{N}{(2k-1)^2}right)^{-t}right)
    left(1-cleft(dfrac{N}{2k-1}right)^{-s}right)right)\[4pt]
    &&timesleft(1-left(1-dfrac1{4k^2}cleft(dfrac{N}{4k^2}right)^{-s}right)
    left(1-dleft(dfrac{N}{2k}right)^{-t}right)right).
    end{cases}tag{11}$$



    Model $(11)$ should be checked theoretically and practically, but it gives the approach to the required estimations.



    The next steps are estimation of parameters $$c,d,s,t$$ and using of obtained model.







    share|cite|improve this answer














    share|cite|improve this answer



    share|cite|improve this answer








    edited 22 hours ago

























    answered Jan 2 at 19:52









    Yuri NegometyanovYuri Negometyanov

    10.9k1727




    10.9k1727












    • @Joseph O'Rourke Approximation can be changed, but parametrization is actual.
      – Yuri Negometyanov
      23 hours ago


















    • @Joseph O'Rourke Approximation can be changed, but parametrization is actual.
      – Yuri Negometyanov
      23 hours ago
















    @Joseph O'Rourke Approximation can be changed, but parametrization is actual.
    – Yuri Negometyanov
    23 hours ago




    @Joseph O'Rourke Approximation can be changed, but parametrization is actual.
    – Yuri Negometyanov
    23 hours ago











    2





    +100









    Since both @awwalker and @mathworker21 mentioned Erdős' conjecture, and because
    a paper discussing this conjecture was just published, I thought I would mention it:




    Erdős Conjecture (1940s or 1950s). If $A subset mathbb{N}$
    satisfies $sum_{n in A} frac{1}{n}= infty$, then
    $A$ contains arbitrarily long arithmetic progressions.




    In




    • Grochow, Joshua. "New applications of the polynomial method: The cap
      set conjecture and beyond." Bulletin of the American Mathematical
      Society
      , Vol.56, No.1, Jan. 2019,


    he says:




    "It remains open even to prove that a set $A$ satisfying the hypothesis contains $3$-term arithmetic progressions."







    share|cite|improve this answer




























      2





      +100









      Since both @awwalker and @mathworker21 mentioned Erdős' conjecture, and because
      a paper discussing this conjecture was just published, I thought I would mention it:




      Erdős Conjecture (1940s or 1950s). If $A subset mathbb{N}$
      satisfies $sum_{n in A} frac{1}{n}= infty$, then
      $A$ contains arbitrarily long arithmetic progressions.




      In




      • Grochow, Joshua. "New applications of the polynomial method: The cap
        set conjecture and beyond." Bulletin of the American Mathematical
        Society
        , Vol.56, No.1, Jan. 2019,


      he says:




      "It remains open even to prove that a set $A$ satisfying the hypothesis contains $3$-term arithmetic progressions."







      share|cite|improve this answer


























        2





        +100







        2





        +100



        2




        +100




        Since both @awwalker and @mathworker21 mentioned Erdős' conjecture, and because
        a paper discussing this conjecture was just published, I thought I would mention it:




        Erdős Conjecture (1940s or 1950s). If $A subset mathbb{N}$
        satisfies $sum_{n in A} frac{1}{n}= infty$, then
        $A$ contains arbitrarily long arithmetic progressions.




        In




        • Grochow, Joshua. "New applications of the polynomial method: The cap
          set conjecture and beyond." Bulletin of the American Mathematical
          Society
          , Vol.56, No.1, Jan. 2019,


        he says:




        "It remains open even to prove that a set $A$ satisfying the hypothesis contains $3$-term arithmetic progressions."







        share|cite|improve this answer














        Since both @awwalker and @mathworker21 mentioned Erdős' conjecture, and because
        a paper discussing this conjecture was just published, I thought I would mention it:




        Erdős Conjecture (1940s or 1950s). If $A subset mathbb{N}$
        satisfies $sum_{n in A} frac{1}{n}= infty$, then
        $A$ contains arbitrarily long arithmetic progressions.




        In




        • Grochow, Joshua. "New applications of the polynomial method: The cap
          set conjecture and beyond." Bulletin of the American Mathematical
          Society
          , Vol.56, No.1, Jan. 2019,


        he says:




        "It remains open even to prove that a set $A$ satisfying the hypothesis contains $3$-term arithmetic progressions."








        share|cite|improve this answer














        share|cite|improve this answer



        share|cite|improve this answer








        edited yesterday


























        community wiki





        2 revs
        Joseph O'Rourke































            draft saved

            draft discarded




















































            Thanks for contributing an answer to Mathematics Stack Exchange!


            • Please be sure to answer the question. Provide details and share your research!

            But avoid



            • Asking for help, clarification, or responding to other answers.

            • Making statements based on opinion; back them up with references or personal experience.


            Use MathJax to format equations. MathJax reference.


            To learn more, see our tips on writing great answers.





            Some of your past answers have not been well-received, and you're in danger of being blocked from answering.


            Please pay close attention to the following guidance:


            • Please be sure to answer the question. Provide details and share your research!

            But avoid



            • Asking for help, clarification, or responding to other answers.

            • Making statements based on opinion; back them up with references or personal experience.


            To learn more, see our tips on writing great answers.




            draft saved


            draft discarded














            StackExchange.ready(
            function () {
            StackExchange.openid.initPostLogin('.new-post-login', 'https%3a%2f%2fmath.stackexchange.com%2fquestions%2f858918%2fa-sequence-that-avoids-both-arithmetic-and-geometric-progressions%23new-answer', 'question_page');
            }
            );

            Post as a guest















            Required, but never shown





















































            Required, but never shown














            Required, but never shown












            Required, but never shown







            Required, but never shown

































            Required, but never shown














            Required, but never shown












            Required, but never shown







            Required, but never shown







            Popular posts from this blog

            1300-talet

            1300-talet

            Display a custom attribute below product name in the front-end Magento 1.9.3.8