How to prove a simple equation? The Next CEO of Stack OverflowProof: For all integers $x$ and $y$, if $x^3+x = y^3+y$ then $x = y$Simple question about proof by contrapositivity.Does there exist a $(m,n)inmathbb N$ such that $m^3-2^n=3$?Proof: For all integers $x$ and $y$, if $x^2+ y^2= 0$ then $x =0$ and $y =0$disprove : $forall n in mathbbN exists m in mathbbN$ such that $n<m<n^2$Proof writing involving propositional logic: (x ∨ y) ≡ ( x ∧ y ) → x ≡ yIs the following statement about rationals true or false?How many massively palindromic primes exist?The Number Theoretic Statement is …Show that $n^2-1+nsqrtd$ is the fundamental unit in $mathbbZ[sqrtd]$ for all $ngeq 3$
How do I align (1) and (2)?
Would this house-rule that treats advantage as a +1 to the roll instead (and disadvantage as -1) and allows them to stack be balanced?
How did people program for Consoles with multiple CPUs?
WOW air has ceased operation, can I get my tickets refunded?
Make solar eclipses exceedingly rare, but still have new moons
Can you be charged for obstruction for refusing to answer questions?
What happened in Rome, when the western empire "fell"?
Newlines in BSD sed vs gsed
Why, when going from special to general relativity, do we just replace partial derivatives with covariant derivatives?
Won the lottery - how do I keep the money?
Does soap repel water?
Which one is the true statement?
What's the best way to handle refactoring a big file?
Method for adding error messages to a dictionary given a key
Axiom Schema vs Axiom
Necessary condition on homology group for a set to be contractible
If Nick Fury and Coulson already knew about aliens (Kree and Skrull) why did they wait until Thor's appearance to start making weapons?
Prepend last line of stdin to entire stdin
Should I tutor a student who I know has cheated on their homework?
How to prove a simple equation?
Why do airplanes bank sharply to the right after air-to-air refueling?
0 rank tensor vs 1D vector
Is French Guiana a (hard) EU border?
Grabbing quick drinks
How to prove a simple equation?
The Next CEO of Stack OverflowProof: For all integers $x$ and $y$, if $x^3+x = y^3+y$ then $x = y$Simple question about proof by contrapositivity.Does there exist a $(m,n)inmathbb N$ such that $m^3-2^n=3$?Proof: For all integers $x$ and $y$, if $x^2+ y^2= 0$ then $x =0$ and $y =0$disprove : $forall n in mathbbN exists m in mathbbN$ such that $n<m<n^2$Proof writing involving propositional logic: (x ∨ y) ≡ ( x ∧ y ) → x ≡ yIs the following statement about rationals true or false?How many massively palindromic primes exist?The Number Theoretic Statement is …Show that $n^2-1+nsqrtd$ is the fundamental unit in $mathbbZ[sqrtd]$ for all $ngeq 3$
$begingroup$
I have reason(empirical calculations) to think the following statement is true:
For any $k in mathbbN$, there exist $s in mathbbN$ such that the expression
$$9*s+3+2^k$$
is a power of $2$.
To me it seems like a silly statement, but I don't know how I would go about proving it. Any ideas, or references?
THank you.
number-theory discrete-mathematics recreational-mathematics
asked 2 hours ago
ReverseFlowReverseFlow
604513
$endgroup$
add a comment |
$begingroup$
I have reason(empirical calculations) to think the following statement is true:
For any $k in mathbbN$, there exist $s in mathbbN$ such that the expression
$$9*s+3+2^k$$
is a power of $2$.
To me it seems like a silly statement, but I don't know how I would go about proving it. Any ideas, or references?
THank you.
number-theory discrete-mathematics recreational-mathematics
asked 2 hours ago
ReverseFlowReverseFlow
604513
$endgroup$
add a comment |
$begingroup$
I have reason(empirical calculations) to think the following statement is true:
For any $k in mathbbN$, there exist $s in mathbbN$ such that the expression
$$9*s+3+2^k$$
is a power of $2$.
To me it seems like a silly statement, but I don't know how I would go about proving it. Any ideas, or references?
THank you.
number-theory discrete-mathematics recreational-mathematics
asked 2 hours ago
ReverseFlowReverseFlow
604513
$endgroup$
I have reason(empirical calculations) to think the following statement is true:
For any $k in mathbbN$, there exist $s in mathbbN$ such that the expression
$$9*s+3+2^k$$
is a power of $2$.
To me it seems like a silly statement, but I don't know how I would go about proving it. Any ideas, or references?
THank you.
number-theory discrete-mathematics recreational-mathematics
number-theory discrete-mathematics recreational-mathematics
asked 2 hours ago
ReverseFlowReverseFlow
604513
asked 2 hours ago
ReverseFlowReverseFlow
604513
asked 2 hours ago
ReverseFlowReverseFlow
604513
asked 2 hours ago
ReverseFlowReverseFlow
604513
asked 2 hours ago
ReverseFlowReverseFlow
604513
604513
add a comment |
add a comment |
5 Answers
5
active
oldest
votes
$begingroup$
The statement that $9s + 3 + 2^k$ is a power of $2$ for some $sinBbbN$ is equivalent to saying $2^k + 3 equiv 2^n pmod 9$ for some $ngt k$. Since the values of $2^kbmod 9$ are the periodic sequence $1,2,4,8,7,5,1,2,4,8,7,5,ldots$ consisting of all values which are not multiples of $3$, this is true.
For example, take $k = 5$. Then $2^k + 3 = 35 equiv 8 pmod 9$ and the next power of $2$ which is congruent to $8$ is $2^9 = 512$. So in this case $s = (512 - 35)/9 = 53$.
answered 2 hours ago
FredHFredH
3,2951022
$endgroup$
add a comment |
$begingroup$
If $9s+3 = 3cdot 2^k$,
this will work.
Then
$3s+1 = 2^k$,
so $3|2^k-1$.
This works for even $k$.
More generally,
it works if
$9s+3 = (2^m-1)2^k$
for some $m$.
To get rid of the 3
requires $m$ even,
so write this as
$9s+3
= (4^m-1)2^k
= 3sum_j=0^m-14^j2^k
$
or
$3s+1
= 2^ksum_j=0^m-14^j
$.
Mod 3,
we want
$1
=2^ksum_j=0^m-14^j
=2^km
$
so if
$2^km = 1 bmod 3$
we are done,
and this can always be done.
answered 1 hour ago
marty cohenmarty cohen
74.9k549130
$endgroup$
add a comment |
$begingroup$
$9cdot s+3+2^k=2^j+k Rightarrow 2^k(2^j-1)-3 equiv 0 mod 9 Rightarrow 2^k(2^j-1) equiv 3 mod 9$
$2^k mod 9$ cycles through $2,4,8,7,5,1,$ etc. so $2^j-1 mod 9$ cycles through $1,3,7,6,4,0$ etc.
For any residue of $2^k$ it is possible to find a residue of $2^j-1$ such that their product equals $3 mod 9$, viz: $2cdot 6; 4cdot 3; 8cdot 6; 7cdot 3; 5cdot 6; 1cdot 3$
So your observation is true.
NB As I typed this, I see that Fred H has given a similar answer.
answered 1 hour ago
Keith BackmanKeith Backman
1,5341812
$endgroup$
add a comment |
$begingroup$
Euler's Theorem tells us $2^6 equiv 1 pmod 9$ and direct calculation shows so
$2^6k + i; i=0...5equiv 1,2,4,8,7,5 pmod 9$.
So $2^m - 2^k equiv 3 pmod 9$ if
$kequiv 0 pmod 6;2^kequiv 1pmod 9$ and $mequiv 2pmod 6; 2^mequiv 4pmod 9$.
$kequiv 1 pmod 6;2^kequiv 2pmod 9$ and $mequiv 5pmod 6; 2^mequiv 5pmod 9$.
$kequiv 2 pmod 6;2^kequiv 4pmod 9$ and $mequiv 4pmod 6; 2^mequiv 7pmod 9$.
$kequiv 3 pmod 6;2^kequiv 8pmod 9$ and $mequiv 1pmod 6; 2^mequiv 2pmod 9$ (So $2^m - 2^k equiv 2-8equiv -6equiv 3 pmod 9$).
$kequiv 4 pmod 6;2^kequiv 7pmod 9$ and $mequiv 0pmod 6; 2^mequiv 1pmod 9$.
$kequiv 5 pmod 6;2^kequiv 5pmod 9$ and $mequiv 3pmod 6; 2^mequiv 9pmod 9$.
So for any $k$ there will exist infinitely many $m > k$ (Actually we don't need $m > k$ as $s$ may be negative but... nice answers are nicer) so that $2^m - 2^k equiv 3 pmod 9$.
So that means for any $k$ there will exist $s$ and $m$ (actually infinitely many $s$ and $m$) so that
$2^m - 2^k = 9s + 3$ or
$9s+3 + 2^k$ a power of $2$.
(I take a dog for a walk and three people post a similar to identical answer. sigh. Anyway hopefully this answer may (or may not) provide a possible fresh take... There's always more than one way to do or explain things.)
answered 1 hour ago
fleabloodfleablood
73.6k22891
$endgroup$
add a comment |
$begingroup$
Suppose $k in mathbbN = mathbbZ_>0$ is given.
Set beginalign*
s &= 2^k + frac13 left( (-2)^k+1 - 1 right) text, and \
n &= (-1)^k+1 + k + 3 text.
endalign*
Then $s$ and $n$ are positive integers and
$$ 9s + 3 + 2^k = 2^n text. $$
This looks like a job for induction, but we can show it directly.
The expression for $n$ is a sum of integers, so $n$ is an integer, and the value of the expression lies in $[k+3-1, k+3+1]$. Since $k > 0$, this entire interval contains only positive numbers, so $n$ is a positive integer.
For $s$, note that $(-2)^k+1 - 1 cong 1^k+1 - 1 cong 1 - 1 cong 0 pmod3$, so the division by $3$ yields an integer. We wish to ensure $s > 0$, so beginalign*
2^k + frac13 left( (-2)^k+1 - 1 right) overset?> 0 \
2^k + frac13 left( (-1)^k+12^k+1 - 1 right) overset?> 0 \
1 + frac13 left( (-1)^k+12^1 - 2^-k right) overset?> 0
endalign*
If $k$ is even, beginalign*
1 + frac13 left( -2 - 2^-k right) overset?> 0 text,
endalign*
$-2 -2^-k in (-3,-2)$, so $1 + frac13 left( -2 - 2^-k right) in (0,1/3)$, all elements of which are positive, so $s$ is positive when $k$ is even. If $k$ is odd, beginalign*
1 + frac13 left( 2 - 2^-k right) overset?> 0 text,
endalign*
$2 - 2^-k in (1,2)$, so $1 + frac13 left( 2 - 2^-k right) in (4/3, 5/3)$, all elements of which are positive, so $s$ is an integer when $k$ is odd. Therefore, $s$ is positive when $k$ is odd. Therefore, $s$ is always a positive integer.
Plugging in the above expressions into the given equation, we have
$$ 9 left( 2^k + frac13 left( (-2)^k+1 - 1 right) right) + 3 + 2^k = 2^(-1)^k+1 + k + 3 text. $$
After a little manipulation, this is
$$ 2^(-1)^k+1 + k + 2 = 5 cdot 2^k - 3(-2)^k text. tag1 $$
First suppose $k$ is even, so $k = 2m$. Substituting this into (1) and simplifying a little, we have
$$ 2^-1 + 2m + 2 = 2 cdot 2^2m text, $$
a tautology.
Then suppose $k$ is odd, so $k = 2m+1$. Sustituting this into (1) and simplifying a little, we have
$$ 2^2m + 4 = 8 cdot 2^2m+1 text, $$
a tautology.
Therefore, the given $s$ and $n$ are positive integers which satisfy the given equation.
Aside: The above choices for $s$ and $n$ do not exhaust the solution set. For instance $(k,s,n) = (2, 131,176,846,746,379,033,713, 70)$ is another solution. (This is implicit in the other answers that use the fact that the powers of $2$ are cyclic modulo $9$.)
answered 1 hour ago
Eric TowersEric Towers
33.3k22370
$endgroup$
add a comment |
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
);
);
Sign up or log in
StackExchange.ready(function ()
StackExchange.helpers.onClickDraftSave('#login-link');
);
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Post as a guest
Required, but never shown
StackExchange.ready(
function ()
StackExchange.openid.initPostLogin('.new-post-login', 'https%3a%2f%2fmath.stackexchange.com%2fquestions%2f3168962%2fhow-to-prove-a-simple-equation%23new-answer', 'question_page');
);
Post as a guest
Required, but never shown
5 Answers
5
active
oldest
votes
5 Answers
5
active
oldest
votes
active
oldest
votes
active
oldest
votes
$begingroup$
The statement that $9s + 3 + 2^k$ is a power of $2$ for some $sinBbbN$ is equivalent to saying $2^k + 3 equiv 2^n pmod 9$ for some $ngt k$. Since the values of $2^kbmod 9$ are the periodic sequence $1,2,4,8,7,5,1,2,4,8,7,5,ldots$ consisting of all values which are not multiples of $3$, this is true.
For example, take $k = 5$. Then $2^k + 3 = 35 equiv 8 pmod 9$ and the next power of $2$ which is congruent to $8$ is $2^9 = 512$. So in this case $s = (512 - 35)/9 = 53$.
answered 2 hours ago
FredHFredH
3,2951022
$endgroup$
add a comment |
$begingroup$
The statement that $9s + 3 + 2^k$ is a power of $2$ for some $sinBbbN$ is equivalent to saying $2^k + 3 equiv 2^n pmod 9$ for some $ngt k$. Since the values of $2^kbmod 9$ are the periodic sequence $1,2,4,8,7,5,1,2,4,8,7,5,ldots$ consisting of all values which are not multiples of $3$, this is true.
For example, take $k = 5$. Then $2^k + 3 = 35 equiv 8 pmod 9$ and the next power of $2$ which is congruent to $8$ is $2^9 = 512$. So in this case $s = (512 - 35)/9 = 53$.
answered 2 hours ago
FredHFredH
3,2951022
$endgroup$
add a comment |
$begingroup$
The statement that $9s + 3 + 2^k$ is a power of $2$ for some $sinBbbN$ is equivalent to saying $2^k + 3 equiv 2^n pmod 9$ for some $ngt k$. Since the values of $2^kbmod 9$ are the periodic sequence $1,2,4,8,7,5,1,2,4,8,7,5,ldots$ consisting of all values which are not multiples of $3$, this is true.
For example, take $k = 5$. Then $2^k + 3 = 35 equiv 8 pmod 9$ and the next power of $2$ which is congruent to $8$ is $2^9 = 512$. So in this case $s = (512 - 35)/9 = 53$.
answered 2 hours ago
FredHFredH
3,2951022
$endgroup$
The statement that $9s + 3 + 2^k$ is a power of $2$ for some $sinBbbN$ is equivalent to saying $2^k + 3 equiv 2^n pmod 9$ for some $ngt k$. Since the values of $2^kbmod 9$ are the periodic sequence $1,2,4,8,7,5,1,2,4,8,7,5,ldots$ consisting of all values which are not multiples of $3$, this is true.
For example, take $k = 5$. Then $2^k + 3 = 35 equiv 8 pmod 9$ and the next power of $2$ which is congruent to $8$ is $2^9 = 512$. So in this case $s = (512 - 35)/9 = 53$.
answered 2 hours ago
FredHFredH
3,2951022
answered 2 hours ago
FredHFredH
3,2951022
answered 2 hours ago
FredHFredH
3,2951022
answered 2 hours ago
FredHFredH
3,2951022
3,2951022
add a comment |
add a comment |
$begingroup$
If $9s+3 = 3cdot 2^k$,
this will work.
Then
$3s+1 = 2^k$,
so $3|2^k-1$.
This works for even $k$.
More generally,
it works if
$9s+3 = (2^m-1)2^k$
for some $m$.
To get rid of the 3
requires $m$ even,
so write this as
$9s+3
= (4^m-1)2^k
= 3sum_j=0^m-14^j2^k
$
or
$3s+1
= 2^ksum_j=0^m-14^j
$.
Mod 3,
we want
$1
=2^ksum_j=0^m-14^j
=2^km
$
so if
$2^km = 1 bmod 3$
we are done,
and this can always be done.
answered 1 hour ago
marty cohenmarty cohen
74.9k549130
$endgroup$
add a comment |
$begingroup$
If $9s+3 = 3cdot 2^k$,
this will work.
Then
$3s+1 = 2^k$,
so $3|2^k-1$.
This works for even $k$.
More generally,
it works if
$9s+3 = (2^m-1)2^k$
for some $m$.
To get rid of the 3
requires $m$ even,
so write this as
$9s+3
= (4^m-1)2^k
= 3sum_j=0^m-14^j2^k
$
or
$3s+1
= 2^ksum_j=0^m-14^j
$.
Mod 3,
we want
$1
=2^ksum_j=0^m-14^j
=2^km
$
so if
$2^km = 1 bmod 3$
we are done,
and this can always be done.
answered 1 hour ago
marty cohenmarty cohen
74.9k549130
$endgroup$
add a comment |
$begingroup$
If $9s+3 = 3cdot 2^k$,
this will work.
Then
$3s+1 = 2^k$,
so $3|2^k-1$.
This works for even $k$.
More generally,
it works if
$9s+3 = (2^m-1)2^k$
for some $m$.
To get rid of the 3
requires $m$ even,
so write this as
$9s+3
= (4^m-1)2^k
= 3sum_j=0^m-14^j2^k
$
or
$3s+1
= 2^ksum_j=0^m-14^j
$.
Mod 3,
we want
$1
=2^ksum_j=0^m-14^j
=2^km
$
so if
$2^km = 1 bmod 3$
we are done,
and this can always be done.
answered 1 hour ago
marty cohenmarty cohen
74.9k549130
$endgroup$
If $9s+3 = 3cdot 2^k$,
this will work.
Then
$3s+1 = 2^k$,
so $3|2^k-1$.
This works for even $k$.
More generally,
it works if
$9s+3 = (2^m-1)2^k$
for some $m$.
To get rid of the 3
requires $m$ even,
so write this as
$9s+3
= (4^m-1)2^k
= 3sum_j=0^m-14^j2^k
$
or
$3s+1
= 2^ksum_j=0^m-14^j
$.
Mod 3,
we want
$1
=2^ksum_j=0^m-14^j
=2^km
$
so if
$2^km = 1 bmod 3$
we are done,
and this can always be done.
answered 1 hour ago
marty cohenmarty cohen
74.9k549130
answered 1 hour ago
marty cohenmarty cohen
74.9k549130
answered 1 hour ago
marty cohenmarty cohen
74.9k549130
answered 1 hour ago
marty cohenmarty cohen
74.9k549130
74.9k549130
add a comment |
add a comment |
$begingroup$
$9cdot s+3+2^k=2^j+k Rightarrow 2^k(2^j-1)-3 equiv 0 mod 9 Rightarrow 2^k(2^j-1) equiv 3 mod 9$
$2^k mod 9$ cycles through $2,4,8,7,5,1,$ etc. so $2^j-1 mod 9$ cycles through $1,3,7,6,4,0$ etc.
For any residue of $2^k$ it is possible to find a residue of $2^j-1$ such that their product equals $3 mod 9$, viz: $2cdot 6; 4cdot 3; 8cdot 6; 7cdot 3; 5cdot 6; 1cdot 3$
So your observation is true.
NB As I typed this, I see that Fred H has given a similar answer.
answered 1 hour ago
Keith BackmanKeith Backman
1,5341812
$endgroup$
add a comment |
$begingroup$
$9cdot s+3+2^k=2^j+k Rightarrow 2^k(2^j-1)-3 equiv 0 mod 9 Rightarrow 2^k(2^j-1) equiv 3 mod 9$
$2^k mod 9$ cycles through $2,4,8,7,5,1,$ etc. so $2^j-1 mod 9$ cycles through $1,3,7,6,4,0$ etc.
For any residue of $2^k$ it is possible to find a residue of $2^j-1$ such that their product equals $3 mod 9$, viz: $2cdot 6; 4cdot 3; 8cdot 6; 7cdot 3; 5cdot 6; 1cdot 3$
So your observation is true.
NB As I typed this, I see that Fred H has given a similar answer.
answered 1 hour ago
Keith BackmanKeith Backman
1,5341812
$endgroup$
add a comment |
$begingroup$
$9cdot s+3+2^k=2^j+k Rightarrow 2^k(2^j-1)-3 equiv 0 mod 9 Rightarrow 2^k(2^j-1) equiv 3 mod 9$
$2^k mod 9$ cycles through $2,4,8,7,5,1,$ etc. so $2^j-1 mod 9$ cycles through $1,3,7,6,4,0$ etc.
For any residue of $2^k$ it is possible to find a residue of $2^j-1$ such that their product equals $3 mod 9$, viz: $2cdot 6; 4cdot 3; 8cdot 6; 7cdot 3; 5cdot 6; 1cdot 3$
So your observation is true.
NB As I typed this, I see that Fred H has given a similar answer.
answered 1 hour ago
Keith BackmanKeith Backman
1,5341812
$endgroup$
$9cdot s+3+2^k=2^j+k Rightarrow 2^k(2^j-1)-3 equiv 0 mod 9 Rightarrow 2^k(2^j-1) equiv 3 mod 9$
$2^k mod 9$ cycles through $2,4,8,7,5,1,$ etc. so $2^j-1 mod 9$ cycles through $1,3,7,6,4,0$ etc.
For any residue of $2^k$ it is possible to find a residue of $2^j-1$ such that their product equals $3 mod 9$, viz: $2cdot 6; 4cdot 3; 8cdot 6; 7cdot 3; 5cdot 6; 1cdot 3$
So your observation is true.
NB As I typed this, I see that Fred H has given a similar answer.
answered 1 hour ago
Keith BackmanKeith Backman
1,5341812
answered 1 hour ago
Keith BackmanKeith Backman
1,5341812
answered 1 hour ago
Keith BackmanKeith Backman
1,5341812
answered 1 hour ago
Keith BackmanKeith Backman
1,5341812
1,5341812
add a comment |
add a comment |
$begingroup$
Euler's Theorem tells us $2^6 equiv 1 pmod 9$ and direct calculation shows so
$2^6k + i; i=0...5equiv 1,2,4,8,7,5 pmod 9$.
So $2^m - 2^k equiv 3 pmod 9$ if
$kequiv 0 pmod 6;2^kequiv 1pmod 9$ and $mequiv 2pmod 6; 2^mequiv 4pmod 9$.
$kequiv 1 pmod 6;2^kequiv 2pmod 9$ and $mequiv 5pmod 6; 2^mequiv 5pmod 9$.
$kequiv 2 pmod 6;2^kequiv 4pmod 9$ and $mequiv 4pmod 6; 2^mequiv 7pmod 9$.
$kequiv 3 pmod 6;2^kequiv 8pmod 9$ and $mequiv 1pmod 6; 2^mequiv 2pmod 9$ (So $2^m - 2^k equiv 2-8equiv -6equiv 3 pmod 9$).
$kequiv 4 pmod 6;2^kequiv 7pmod 9$ and $mequiv 0pmod 6; 2^mequiv 1pmod 9$.
$kequiv 5 pmod 6;2^kequiv 5pmod 9$ and $mequiv 3pmod 6; 2^mequiv 9pmod 9$.
So for any $k$ there will exist infinitely many $m > k$ (Actually we don't need $m > k$ as $s$ may be negative but... nice answers are nicer) so that $2^m - 2^k equiv 3 pmod 9$.
So that means for any $k$ there will exist $s$ and $m$ (actually infinitely many $s$ and $m$) so that
$2^m - 2^k = 9s + 3$ or
$9s+3 + 2^k$ a power of $2$.
(I take a dog for a walk and three people post a similar to identical answer. sigh. Anyway hopefully this answer may (or may not) provide a possible fresh take... There's always more than one way to do or explain things.)
answered 1 hour ago
fleabloodfleablood
73.6k22891
$endgroup$
add a comment |
$begingroup$
Euler's Theorem tells us $2^6 equiv 1 pmod 9$ and direct calculation shows so
$2^6k + i; i=0...5equiv 1,2,4,8,7,5 pmod 9$.
So $2^m - 2^k equiv 3 pmod 9$ if
$kequiv 0 pmod 6;2^kequiv 1pmod 9$ and $mequiv 2pmod 6; 2^mequiv 4pmod 9$.
$kequiv 1 pmod 6;2^kequiv 2pmod 9$ and $mequiv 5pmod 6; 2^mequiv 5pmod 9$.
$kequiv 2 pmod 6;2^kequiv 4pmod 9$ and $mequiv 4pmod 6; 2^mequiv 7pmod 9$.
$kequiv 3 pmod 6;2^kequiv 8pmod 9$ and $mequiv 1pmod 6; 2^mequiv 2pmod 9$ (So $2^m - 2^k equiv 2-8equiv -6equiv 3 pmod 9$).
$kequiv 4 pmod 6;2^kequiv 7pmod 9$ and $mequiv 0pmod 6; 2^mequiv 1pmod 9$.
$kequiv 5 pmod 6;2^kequiv 5pmod 9$ and $mequiv 3pmod 6; 2^mequiv 9pmod 9$.
So for any $k$ there will exist infinitely many $m > k$ (Actually we don't need $m > k$ as $s$ may be negative but... nice answers are nicer) so that $2^m - 2^k equiv 3 pmod 9$.
So that means for any $k$ there will exist $s$ and $m$ (actually infinitely many $s$ and $m$) so that
$2^m - 2^k = 9s + 3$ or
$9s+3 + 2^k$ a power of $2$.
(I take a dog for a walk and three people post a similar to identical answer. sigh. Anyway hopefully this answer may (or may not) provide a possible fresh take... There's always more than one way to do or explain things.)
answered 1 hour ago
fleabloodfleablood
73.6k22891
$endgroup$
add a comment |
$begingroup$
Euler's Theorem tells us $2^6 equiv 1 pmod 9$ and direct calculation shows so
$2^6k + i; i=0...5equiv 1,2,4,8,7,5 pmod 9$.
So $2^m - 2^k equiv 3 pmod 9$ if
$kequiv 0 pmod 6;2^kequiv 1pmod 9$ and $mequiv 2pmod 6; 2^mequiv 4pmod 9$.
$kequiv 1 pmod 6;2^kequiv 2pmod 9$ and $mequiv 5pmod 6; 2^mequiv 5pmod 9$.
$kequiv 2 pmod 6;2^kequiv 4pmod 9$ and $mequiv 4pmod 6; 2^mequiv 7pmod 9$.
$kequiv 3 pmod 6;2^kequiv 8pmod 9$ and $mequiv 1pmod 6; 2^mequiv 2pmod 9$ (So $2^m - 2^k equiv 2-8equiv -6equiv 3 pmod 9$).
$kequiv 4 pmod 6;2^kequiv 7pmod 9$ and $mequiv 0pmod 6; 2^mequiv 1pmod 9$.
$kequiv 5 pmod 6;2^kequiv 5pmod 9$ and $mequiv 3pmod 6; 2^mequiv 9pmod 9$.
So for any $k$ there will exist infinitely many $m > k$ (Actually we don't need $m > k$ as $s$ may be negative but... nice answers are nicer) so that $2^m - 2^k equiv 3 pmod 9$.
So that means for any $k$ there will exist $s$ and $m$ (actually infinitely many $s$ and $m$) so that
$2^m - 2^k = 9s + 3$ or
$9s+3 + 2^k$ a power of $2$.
(I take a dog for a walk and three people post a similar to identical answer. sigh. Anyway hopefully this answer may (or may not) provide a possible fresh take... There's always more than one way to do or explain things.)
answered 1 hour ago
fleabloodfleablood
73.6k22891
$endgroup$
Euler's Theorem tells us $2^6 equiv 1 pmod 9$ and direct calculation shows so
$2^6k + i; i=0...5equiv 1,2,4,8,7,5 pmod 9$.
So $2^m - 2^k equiv 3 pmod 9$ if
$kequiv 0 pmod 6;2^kequiv 1pmod 9$ and $mequiv 2pmod 6; 2^mequiv 4pmod 9$.
$kequiv 1 pmod 6;2^kequiv 2pmod 9$ and $mequiv 5pmod 6; 2^mequiv 5pmod 9$.
$kequiv 2 pmod 6;2^kequiv 4pmod 9$ and $mequiv 4pmod 6; 2^mequiv 7pmod 9$.
$kequiv 3 pmod 6;2^kequiv 8pmod 9$ and $mequiv 1pmod 6; 2^mequiv 2pmod 9$ (So $2^m - 2^k equiv 2-8equiv -6equiv 3 pmod 9$).
$kequiv 4 pmod 6;2^kequiv 7pmod 9$ and $mequiv 0pmod 6; 2^mequiv 1pmod 9$.
$kequiv 5 pmod 6;2^kequiv 5pmod 9$ and $mequiv 3pmod 6; 2^mequiv 9pmod 9$.
So for any $k$ there will exist infinitely many $m > k$ (Actually we don't need $m > k$ as $s$ may be negative but... nice answers are nicer) so that $2^m - 2^k equiv 3 pmod 9$.
So that means for any $k$ there will exist $s$ and $m$ (actually infinitely many $s$ and $m$) so that
$2^m - 2^k = 9s + 3$ or
$9s+3 + 2^k$ a power of $2$.
(I take a dog for a walk and three people post a similar to identical answer. sigh. Anyway hopefully this answer may (or may not) provide a possible fresh take... There's always more than one way to do or explain things.)
answered 1 hour ago
fleabloodfleablood
73.6k22891
edited 1 hour ago
answered 1 hour ago
fleabloodfleablood
73.6k22891
answered 1 hour ago
fleabloodfleablood
73.6k22891
answered 1 hour ago
fleabloodfleablood
73.6k22891
73.6k22891
add a comment |
add a comment |
$begingroup$
Suppose $k in mathbbN = mathbbZ_>0$ is given.
Set beginalign*
s &= 2^k + frac13 left( (-2)^k+1 - 1 right) text, and \
n &= (-1)^k+1 + k + 3 text.
endalign*
Then $s$ and $n$ are positive integers and
$$ 9s + 3 + 2^k = 2^n text. $$
This looks like a job for induction, but we can show it directly.
The expression for $n$ is a sum of integers, so $n$ is an integer, and the value of the expression lies in $[k+3-1, k+3+1]$. Since $k > 0$, this entire interval contains only positive numbers, so $n$ is a positive integer.
For $s$, note that $(-2)^k+1 - 1 cong 1^k+1 - 1 cong 1 - 1 cong 0 pmod3$, so the division by $3$ yields an integer. We wish to ensure $s > 0$, so beginalign*
2^k + frac13 left( (-2)^k+1 - 1 right) overset?> 0 \
2^k + frac13 left( (-1)^k+12^k+1 - 1 right) overset?> 0 \
1 + frac13 left( (-1)^k+12^1 - 2^-k right) overset?> 0
endalign*
If $k$ is even, beginalign*
1 + frac13 left( -2 - 2^-k right) overset?> 0 text,
endalign*
$-2 -2^-k in (-3,-2)$, so $1 + frac13 left( -2 - 2^-k right) in (0,1/3)$, all elements of which are positive, so $s$ is positive when $k$ is even. If $k$ is odd, beginalign*
1 + frac13 left( 2 - 2^-k right) overset?> 0 text,
endalign*
$2 - 2^-k in (1,2)$, so $1 + frac13 left( 2 - 2^-k right) in (4/3, 5/3)$, all elements of which are positive, so $s$ is an integer when $k$ is odd. Therefore, $s$ is positive when $k$ is odd. Therefore, $s$ is always a positive integer.
Plugging in the above expressions into the given equation, we have
$$ 9 left( 2^k + frac13 left( (-2)^k+1 - 1 right) right) + 3 + 2^k = 2^(-1)^k+1 + k + 3 text. $$
After a little manipulation, this is
$$ 2^(-1)^k+1 + k + 2 = 5 cdot 2^k - 3(-2)^k text. tag1 $$
First suppose $k$ is even, so $k = 2m$. Substituting this into (1) and simplifying a little, we have
$$ 2^-1 + 2m + 2 = 2 cdot 2^2m text, $$
a tautology.
Then suppose $k$ is odd, so $k = 2m+1$. Sustituting this into (1) and simplifying a little, we have
$$ 2^2m + 4 = 8 cdot 2^2m+1 text, $$
a tautology.
Therefore, the given $s$ and $n$ are positive integers which satisfy the given equation.
Aside: The above choices for $s$ and $n$ do not exhaust the solution set. For instance $(k,s,n) = (2, 131,176,846,746,379,033,713, 70)$ is another solution. (This is implicit in the other answers that use the fact that the powers of $2$ are cyclic modulo $9$.)
answered 1 hour ago
Eric TowersEric Towers
33.3k22370
$endgroup$
add a comment |
$begingroup$
Suppose $k in mathbbN = mathbbZ_>0$ is given.
Set beginalign*
s &= 2^k + frac13 left( (-2)^k+1 - 1 right) text, and \
n &= (-1)^k+1 + k + 3 text.
endalign*
Then $s$ and $n$ are positive integers and
$$ 9s + 3 + 2^k = 2^n text. $$
This looks like a job for induction, but we can show it directly.
The expression for $n$ is a sum of integers, so $n$ is an integer, and the value of the expression lies in $[k+3-1, k+3+1]$. Since $k > 0$, this entire interval contains only positive numbers, so $n$ is a positive integer.
For $s$, note that $(-2)^k+1 - 1 cong 1^k+1 - 1 cong 1 - 1 cong 0 pmod3$, so the division by $3$ yields an integer. We wish to ensure $s > 0$, so beginalign*
2^k + frac13 left( (-2)^k+1 - 1 right) overset?> 0 \
2^k + frac13 left( (-1)^k+12^k+1 - 1 right) overset?> 0 \
1 + frac13 left( (-1)^k+12^1 - 2^-k right) overset?> 0
endalign*
If $k$ is even, beginalign*
1 + frac13 left( -2 - 2^-k right) overset?> 0 text,
endalign*
$-2 -2^-k in (-3,-2)$, so $1 + frac13 left( -2 - 2^-k right) in (0,1/3)$, all elements of which are positive, so $s$ is positive when $k$ is even. If $k$ is odd, beginalign*
1 + frac13 left( 2 - 2^-k right) overset?> 0 text,
endalign*
$2 - 2^-k in (1,2)$, so $1 + frac13 left( 2 - 2^-k right) in (4/3, 5/3)$, all elements of which are positive, so $s$ is an integer when $k$ is odd. Therefore, $s$ is positive when $k$ is odd. Therefore, $s$ is always a positive integer.
Plugging in the above expressions into the given equation, we have
$$ 9 left( 2^k + frac13 left( (-2)^k+1 - 1 right) right) + 3 + 2^k = 2^(-1)^k+1 + k + 3 text. $$
After a little manipulation, this is
$$ 2^(-1)^k+1 + k + 2 = 5 cdot 2^k - 3(-2)^k text. tag1 $$
First suppose $k$ is even, so $k = 2m$. Substituting this into (1) and simplifying a little, we have
$$ 2^-1 + 2m + 2 = 2 cdot 2^2m text, $$
a tautology.
Then suppose $k$ is odd, so $k = 2m+1$. Sustituting this into (1) and simplifying a little, we have
$$ 2^2m + 4 = 8 cdot 2^2m+1 text, $$
a tautology.
Therefore, the given $s$ and $n$ are positive integers which satisfy the given equation.
Aside: The above choices for $s$ and $n$ do not exhaust the solution set. For instance $(k,s,n) = (2, 131,176,846,746,379,033,713, 70)$ is another solution. (This is implicit in the other answers that use the fact that the powers of $2$ are cyclic modulo $9$.)
answered 1 hour ago
Eric TowersEric Towers
33.3k22370
$endgroup$
add a comment |
$begingroup$
Suppose $k in mathbbN = mathbbZ_>0$ is given.
Set beginalign*
s &= 2^k + frac13 left( (-2)^k+1 - 1 right) text, and \
n &= (-1)^k+1 + k + 3 text.
endalign*
Then $s$ and $n$ are positive integers and
$$ 9s + 3 + 2^k = 2^n text. $$
This looks like a job for induction, but we can show it directly.
The expression for $n$ is a sum of integers, so $n$ is an integer, and the value of the expression lies in $[k+3-1, k+3+1]$. Since $k > 0$, this entire interval contains only positive numbers, so $n$ is a positive integer.
For $s$, note that $(-2)^k+1 - 1 cong 1^k+1 - 1 cong 1 - 1 cong 0 pmod3$, so the division by $3$ yields an integer. We wish to ensure $s > 0$, so beginalign*
2^k + frac13 left( (-2)^k+1 - 1 right) overset?> 0 \
2^k + frac13 left( (-1)^k+12^k+1 - 1 right) overset?> 0 \
1 + frac13 left( (-1)^k+12^1 - 2^-k right) overset?> 0
endalign*
If $k$ is even, beginalign*
1 + frac13 left( -2 - 2^-k right) overset?> 0 text,
endalign*
$-2 -2^-k in (-3,-2)$, so $1 + frac13 left( -2 - 2^-k right) in (0,1/3)$, all elements of which are positive, so $s$ is positive when $k$ is even. If $k$ is odd, beginalign*
1 + frac13 left( 2 - 2^-k right) overset?> 0 text,
endalign*
$2 - 2^-k in (1,2)$, so $1 + frac13 left( 2 - 2^-k right) in (4/3, 5/3)$, all elements of which are positive, so $s$ is an integer when $k$ is odd. Therefore, $s$ is positive when $k$ is odd. Therefore, $s$ is always a positive integer.
Plugging in the above expressions into the given equation, we have
$$ 9 left( 2^k + frac13 left( (-2)^k+1 - 1 right) right) + 3 + 2^k = 2^(-1)^k+1 + k + 3 text. $$
After a little manipulation, this is
$$ 2^(-1)^k+1 + k + 2 = 5 cdot 2^k - 3(-2)^k text. tag1 $$
First suppose $k$ is even, so $k = 2m$. Substituting this into (1) and simplifying a little, we have
$$ 2^-1 + 2m + 2 = 2 cdot 2^2m text, $$
a tautology.
Then suppose $k$ is odd, so $k = 2m+1$. Sustituting this into (1) and simplifying a little, we have
$$ 2^2m + 4 = 8 cdot 2^2m+1 text, $$
a tautology.
Therefore, the given $s$ and $n$ are positive integers which satisfy the given equation.
Aside: The above choices for $s$ and $n$ do not exhaust the solution set. For instance $(k,s,n) = (2, 131,176,846,746,379,033,713, 70)$ is another solution. (This is implicit in the other answers that use the fact that the powers of $2$ are cyclic modulo $9$.)
answered 1 hour ago
Eric TowersEric Towers
33.3k22370
$endgroup$
Suppose $k in mathbbN = mathbbZ_>0$ is given.
Set beginalign*
s &= 2^k + frac13 left( (-2)^k+1 - 1 right) text, and \
n &= (-1)^k+1 + k + 3 text.
endalign*
Then $s$ and $n$ are positive integers and
$$ 9s + 3 + 2^k = 2^n text. $$
This looks like a job for induction, but we can show it directly.
The expression for $n$ is a sum of integers, so $n$ is an integer, and the value of the expression lies in $[k+3-1, k+3+1]$. Since $k > 0$, this entire interval contains only positive numbers, so $n$ is a positive integer.
For $s$, note that $(-2)^k+1 - 1 cong 1^k+1 - 1 cong 1 - 1 cong 0 pmod3$, so the division by $3$ yields an integer. We wish to ensure $s > 0$, so beginalign*
2^k + frac13 left( (-2)^k+1 - 1 right) overset?> 0 \
2^k + frac13 left( (-1)^k+12^k+1 - 1 right) overset?> 0 \
1 + frac13 left( (-1)^k+12^1 - 2^-k right) overset?> 0
endalign*
If $k$ is even, beginalign*
1 + frac13 left( -2 - 2^-k right) overset?> 0 text,
endalign*
$-2 -2^-k in (-3,-2)$, so $1 + frac13 left( -2 - 2^-k right) in (0,1/3)$, all elements of which are positive, so $s$ is positive when $k$ is even. If $k$ is odd, beginalign*
1 + frac13 left( 2 - 2^-k right) overset?> 0 text,
endalign*
$2 - 2^-k in (1,2)$, so $1 + frac13 left( 2 - 2^-k right) in (4/3, 5/3)$, all elements of which are positive, so $s$ is an integer when $k$ is odd. Therefore, $s$ is positive when $k$ is odd. Therefore, $s$ is always a positive integer.
Plugging in the above expressions into the given equation, we have
$$ 9 left( 2^k + frac13 left( (-2)^k+1 - 1 right) right) + 3 + 2^k = 2^(-1)^k+1 + k + 3 text. $$
After a little manipulation, this is
$$ 2^(-1)^k+1 + k + 2 = 5 cdot 2^k - 3(-2)^k text. tag1 $$
First suppose $k$ is even, so $k = 2m$. Substituting this into (1) and simplifying a little, we have
$$ 2^-1 + 2m + 2 = 2 cdot 2^2m text, $$
a tautology.
Then suppose $k$ is odd, so $k = 2m+1$. Sustituting this into (1) and simplifying a little, we have
$$ 2^2m + 4 = 8 cdot 2^2m+1 text, $$
a tautology.
Therefore, the given $s$ and $n$ are positive integers which satisfy the given equation.
Aside: The above choices for $s$ and $n$ do not exhaust the solution set. For instance $(k,s,n) = (2, 131,176,846,746,379,033,713, 70)$ is another solution. (This is implicit in the other answers that use the fact that the powers of $2$ are cyclic modulo $9$.)
answered 1 hour ago
Eric TowersEric Towers
33.3k22370
answered 1 hour ago
Eric TowersEric Towers
33.3k22370
answered 1 hour ago
Eric TowersEric Towers
33.3k22370
answered 1 hour ago
Eric TowersEric Towers
33.3k22370
33.3k22370
add a comment |
add a comment |
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.
Sign up or log in
StackExchange.ready(function ()
StackExchange.helpers.onClickDraftSave('#login-link');
);
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Post as a guest
Required, but never shown
StackExchange.ready(
function ()
StackExchange.openid.initPostLogin('.new-post-login', 'https%3a%2f%2fmath.stackexchange.com%2fquestions%2f3168962%2fhow-to-prove-a-simple-equation%23new-answer', 'question_page');
);
Post as a guest
Required, but never shown
Sign up or log in
StackExchange.ready(function ()
StackExchange.helpers.onClickDraftSave('#login-link');
);
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Post as a guest
Required, but never shown
Sign up or log in
StackExchange.ready(function ()
StackExchange.helpers.onClickDraftSave('#login-link');
);
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Post as a guest
Required, but never shown
Sign up or log in
StackExchange.ready(function ()
StackExchange.helpers.onClickDraftSave('#login-link');
);
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
Sign up using Google
Sign up using Facebook
Sign up using Email and Password
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
