How many integer solutions are there for $x_1+x_2+x_3+x_4+x_5=75$, with $1 leq i leq 5, x_1=x_5$?
$begingroup$
How many integer solutions are there for $x_1+x_2+x_3+x_4+x_5=75$, with $1leq i leq 5,$ and $ x_1=x_5$ ?
I think I understand that if $x_1=x_5$ wasn't part of it, then it would be $binom{n-1}{k-1}.$
But if someone could explain how I deal with the $x_1=x_5$ that would be great!
combinatorics combinations
edited Jan 22 at 19:33
jordan_glen
1
asked Jan 22 at 19:24
EveresttMLEveresttML
11
$endgroup$
add a comment |
$begingroup$
How many integer solutions are there for $x_1+x_2+x_3+x_4+x_5=75$, with $1leq i leq 5,$ and $ x_1=x_5$ ?
I think I understand that if $x_1=x_5$ wasn't part of it, then it would be $binom{n-1}{k-1}.$
But if someone could explain how I deal with the $x_1=x_5$ that would be great!
combinatorics combinations
edited Jan 22 at 19:33
jordan_glen
1
asked Jan 22 at 19:24
EveresttMLEveresttML
11
$endgroup$
$begingroup$
In your "understanding," what would $n$ and $k$ be for this case? Does your formula work for a simple small case, such as $x_1 + x_2 + x_3 = 5$? And why not simply ask your question: $2 x_1 + x_2 + x_3 + x_4 = 75$?
$endgroup$
– David G. Stork
Jan 22 at 19:30
1
$begingroup$
Think of distributing 75 cookies among five people. Except among those five people there are two brothers who need to receive the same number of cookies! Feel free to ask for any clarifications and I shall help!
$endgroup$
– The Jade Emperor
Jan 22 at 19:36
$begingroup$
To my understanding n = 5 and k = 3.
$endgroup$
– EveresttML
Jan 22 at 19:47
add a comment |
$begingroup$
How many integer solutions are there for $x_1+x_2+x_3+x_4+x_5=75$, with $1leq i leq 5,$ and $ x_1=x_5$ ?
I think I understand that if $x_1=x_5$ wasn't part of it, then it would be $binom{n-1}{k-1}.$
But if someone could explain how I deal with the $x_1=x_5$ that would be great!
combinatorics combinations
edited Jan 22 at 19:33
jordan_glen
1
asked Jan 22 at 19:24
EveresttMLEveresttML
11
$endgroup$
How many integer solutions are there for $x_1+x_2+x_3+x_4+x_5=75$, with $1leq i leq 5,$ and $ x_1=x_5$ ?
I think I understand that if $x_1=x_5$ wasn't part of it, then it would be $binom{n-1}{k-1}.$
But if someone could explain how I deal with the $x_1=x_5$ that would be great!
combinatorics combinations
combinatorics combinations
edited Jan 22 at 19:33
jordan_glen
1
asked Jan 22 at 19:24
EveresttMLEveresttML
11
edited Jan 22 at 19:33
jordan_glen
1
asked Jan 22 at 19:24
EveresttMLEveresttML
11
edited Jan 22 at 19:33
jordan_glen
1
edited Jan 22 at 19:33
jordan_glen
1
edited Jan 22 at 19:33
jordan_glen
1
1
asked Jan 22 at 19:24
EveresttMLEveresttML
11
asked Jan 22 at 19:24
EveresttMLEveresttML
11
asked Jan 22 at 19:24
EveresttMLEveresttML
11
11
$begingroup$
In your "understanding," what would $n$ and $k$ be for this case? Does your formula work for a simple small case, such as $x_1 + x_2 + x_3 = 5$? And why not simply ask your question: $2 x_1 + x_2 + x_3 + x_4 = 75$?
$endgroup$
– David G. Stork
Jan 22 at 19:30
1
$begingroup$
Think of distributing 75 cookies among five people. Except among those five people there are two brothers who need to receive the same number of cookies! Feel free to ask for any clarifications and I shall help!
$endgroup$
– The Jade Emperor
Jan 22 at 19:36
$begingroup$
To my understanding n = 5 and k = 3.
$endgroup$
– EveresttML
Jan 22 at 19:47
add a comment |
$begingroup$
In your "understanding," what would $n$ and $k$ be for this case? Does your formula work for a simple small case, such as $x_1 + x_2 + x_3 = 5$? And why not simply ask your question: $2 x_1 + x_2 + x_3 + x_4 = 75$?
$endgroup$
– David G. Stork
Jan 22 at 19:30
1
$begingroup$
Think of distributing 75 cookies among five people. Except among those five people there are two brothers who need to receive the same number of cookies! Feel free to ask for any clarifications and I shall help!
$endgroup$
– The Jade Emperor
Jan 22 at 19:36
$begingroup$
To my understanding n = 5 and k = 3.
$endgroup$
– EveresttML
Jan 22 at 19:47
$begingroup$
In your "understanding," what would $n$ and $k$ be for this case? Does your formula work for a simple small case, such as $x_1 + x_2 + x_3 = 5$? And why not simply ask your question: $2 x_1 + x_2 + x_3 + x_4 = 75$?
$endgroup$
– David G. Stork
Jan 22 at 19:30
$begingroup$
In your "understanding," what would $n$ and $k$ be for this case? Does your formula work for a simple small case, such as $x_1 + x_2 + x_3 = 5$? And why not simply ask your question: $2 x_1 + x_2 + x_3 + x_4 = 75$?
$endgroup$
– David G. Stork
Jan 22 at 19:30
1
1
$begingroup$
Think of distributing 75 cookies among five people. Except among those five people there are two brothers who need to receive the same number of cookies! Feel free to ask for any clarifications and I shall help!
$endgroup$
– The Jade Emperor
Jan 22 at 19:36
$begingroup$
Think of distributing 75 cookies among five people. Except among those five people there are two brothers who need to receive the same number of cookies! Feel free to ask for any clarifications and I shall help!
$endgroup$
– The Jade Emperor
Jan 22 at 19:36
$begingroup$
To my understanding n = 5 and k = 3.
$endgroup$
– EveresttML
Jan 22 at 19:47
$begingroup$
To my understanding n = 5 and k = 3.
$endgroup$
– EveresttML
Jan 22 at 19:47
add a comment |
3 Answers
3
active
oldest
votes
$begingroup$
Remember if $x_1=x_5$ this expression can be rewritten as $2x_1+x_2+x_3+x_4=75$
This implies $3leq x_2+x_3+x_4leq73$ and that sum is odd. Can you find how many ways this is true
answered Jan 22 at 19:36
Rhys HughesRhys Hughes
6,9441530
$endgroup$
$begingroup$
This would look better in a comment.. :)
$endgroup$
– The Jade Emperor
Jan 22 at 19:37
add a comment |
$begingroup$
Hint: Consider calculating how many positive integer solutions there are to $$2x_1 + x_2 + x_3 + x_4= 75;?$$
answered Jan 22 at 19:36
jordan_glenjordan_glen
1
$endgroup$
2
$begingroup$
This would look better in a comment.. :)
$endgroup$
– The Jade Emperor
Jan 22 at 19:37
add a comment |
$begingroup$
I haven't done combinatorics in a long time so I might not give you the correct answer but here are some thoughts:
First off, perhaps you should clarify/consider if zeros are allowed. Let's suppose this is so. Think about how your formula can be justified combinatorially: using balls and walls. You can read that here: https://math.dartmouth.edu/archive/m68f09/public_html/m68l02.pdf
I would think of a simpler case. writing 5 as a sum of 4 parts c1, c2, c3 and c4. My idea would then be that we would have 3 cases: c1=c4=0,1 or 2 (3 won't do it). Also notice that I'm using a multiple of 5 for a reason. I guess you would have to take the floor or ceiling function of 75/2.
We're gonna have to use 3 walls (k-1 in your formula). Case 1 looks like this:
$underset{c1}{}|underset{c2}{text{some balls}}|underset{c3}{text{some balls}}|underset{c4}{}$. Of course, under "some balls" we know we have 5 of them and
c1 and c4 are chosen to have none. The problem then becomes: in how many ways can we write 5 has a sum of 2 nonnegative integers? Here, n=5 and k=1.
Case 2 has c1=c4=1 so we have the question: in how many ways can we write 5-2=3 as a sum of 2 nonnegative integers (remaining balls)? Run through all the cases and add them up.
Does this makes sense? Maybe there's a way easier way to solve this but hey, its an idea. What I'm saying is that my strategy would be to consider the actual proof and see what modifications need to be made
answered Jan 22 at 20:49
JayJay
296
$endgroup$
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
$begingroup$
Remember if $x_1=x_5$ this expression can be rewritten as $2x_1+x_2+x_3+x_4=75$
This implies $3leq x_2+x_3+x_4leq73$ and that sum is odd. Can you find how many ways this is true
answered Jan 22 at 19:36
Rhys HughesRhys Hughes
6,9441530
$endgroup$
$begingroup$
This would look better in a comment.. :)
$endgroup$
– The Jade Emperor
Jan 22 at 19:37
add a comment |
$begingroup$
Remember if $x_1=x_5$ this expression can be rewritten as $2x_1+x_2+x_3+x_4=75$
This implies $3leq x_2+x_3+x_4leq73$ and that sum is odd. Can you find how many ways this is true
answered Jan 22 at 19:36
Rhys HughesRhys Hughes
6,9441530
$endgroup$
$begingroup$
This would look better in a comment.. :)
$endgroup$
– The Jade Emperor
Jan 22 at 19:37
add a comment |
$begingroup$
Remember if $x_1=x_5$ this expression can be rewritten as $2x_1+x_2+x_3+x_4=75$
This implies $3leq x_2+x_3+x_4leq73$ and that sum is odd. Can you find how many ways this is true
answered Jan 22 at 19:36
Rhys HughesRhys Hughes
6,9441530
$endgroup$
Remember if $x_1=x_5$ this expression can be rewritten as $2x_1+x_2+x_3+x_4=75$
This implies $3leq x_2+x_3+x_4leq73$ and that sum is odd. Can you find how many ways this is true
answered Jan 22 at 19:36
Rhys HughesRhys Hughes
6,9441530
answered Jan 22 at 19:36
Rhys HughesRhys Hughes
6,9441530
answered Jan 22 at 19:36
Rhys HughesRhys Hughes
6,9441530
answered Jan 22 at 19:36
Rhys HughesRhys Hughes
6,9441530
6,9441530
$begingroup$
This would look better in a comment.. :)
$endgroup$
– The Jade Emperor
Jan 22 at 19:37
add a comment |
$begingroup$
This would look better in a comment.. :)
$endgroup$
– The Jade Emperor
Jan 22 at 19:37
$begingroup$
This would look better in a comment.. :)
$endgroup$
– The Jade Emperor
Jan 22 at 19:37
$begingroup$
This would look better in a comment.. :)
$endgroup$
– The Jade Emperor
Jan 22 at 19:37
add a comment |
$begingroup$
Hint: Consider calculating how many positive integer solutions there are to $$2x_1 + x_2 + x_3 + x_4= 75;?$$
answered Jan 22 at 19:36
jordan_glenjordan_glen
1
$endgroup$
2
$begingroup$
This would look better in a comment.. :)
$endgroup$
– The Jade Emperor
Jan 22 at 19:37
add a comment |
$begingroup$
Hint: Consider calculating how many positive integer solutions there are to $$2x_1 + x_2 + x_3 + x_4= 75;?$$
answered Jan 22 at 19:36
jordan_glenjordan_glen
1
$endgroup$
2
$begingroup$
This would look better in a comment.. :)
$endgroup$
– The Jade Emperor
Jan 22 at 19:37
add a comment |
$begingroup$
Hint: Consider calculating how many positive integer solutions there are to $$2x_1 + x_2 + x_3 + x_4= 75;?$$
answered Jan 22 at 19:36
jordan_glenjordan_glen
1
$endgroup$
Hint: Consider calculating how many positive integer solutions there are to $$2x_1 + x_2 + x_3 + x_4= 75;?$$
answered Jan 22 at 19:36
jordan_glenjordan_glen
1
edited Jan 22 at 19:38
answered Jan 22 at 19:36
jordan_glenjordan_glen
1
answered Jan 22 at 19:36
jordan_glenjordan_glen
1
answered Jan 22 at 19:36
jordan_glenjordan_glen
1
1
2
$begingroup$
This would look better in a comment.. :)
$endgroup$
– The Jade Emperor
Jan 22 at 19:37
add a comment |
2
$begingroup$
This would look better in a comment.. :)
$endgroup$
– The Jade Emperor
Jan 22 at 19:37
2
2
$begingroup$
This would look better in a comment.. :)
$endgroup$
– The Jade Emperor
Jan 22 at 19:37
$begingroup$
This would look better in a comment.. :)
$endgroup$
– The Jade Emperor
Jan 22 at 19:37
add a comment |
$begingroup$
I haven't done combinatorics in a long time so I might not give you the correct answer but here are some thoughts:
First off, perhaps you should clarify/consider if zeros are allowed. Let's suppose this is so. Think about how your formula can be justified combinatorially: using balls and walls. You can read that here: https://math.dartmouth.edu/archive/m68f09/public_html/m68l02.pdf
I would think of a simpler case. writing 5 as a sum of 4 parts c1, c2, c3 and c4. My idea would then be that we would have 3 cases: c1=c4=0,1 or 2 (3 won't do it). Also notice that I'm using a multiple of 5 for a reason. I guess you would have to take the floor or ceiling function of 75/2.
We're gonna have to use 3 walls (k-1 in your formula). Case 1 looks like this:
$underset{c1}{}|underset{c2}{text{some balls}}|underset{c3}{text{some balls}}|underset{c4}{}$. Of course, under "some balls" we know we have 5 of them and
c1 and c4 are chosen to have none. The problem then becomes: in how many ways can we write 5 has a sum of 2 nonnegative integers? Here, n=5 and k=1.
Case 2 has c1=c4=1 so we have the question: in how many ways can we write 5-2=3 as a sum of 2 nonnegative integers (remaining balls)? Run through all the cases and add them up.
Does this makes sense? Maybe there's a way easier way to solve this but hey, its an idea. What I'm saying is that my strategy would be to consider the actual proof and see what modifications need to be made
answered Jan 22 at 20:49
JayJay
296
$endgroup$
add a comment |
$begingroup$
I haven't done combinatorics in a long time so I might not give you the correct answer but here are some thoughts:
First off, perhaps you should clarify/consider if zeros are allowed. Let's suppose this is so. Think about how your formula can be justified combinatorially: using balls and walls. You can read that here: https://math.dartmouth.edu/archive/m68f09/public_html/m68l02.pdf
I would think of a simpler case. writing 5 as a sum of 4 parts c1, c2, c3 and c4. My idea would then be that we would have 3 cases: c1=c4=0,1 or 2 (3 won't do it). Also notice that I'm using a multiple of 5 for a reason. I guess you would have to take the floor or ceiling function of 75/2.
We're gonna have to use 3 walls (k-1 in your formula). Case 1 looks like this:
$underset{c1}{}|underset{c2}{text{some balls}}|underset{c3}{text{some balls}}|underset{c4}{}$. Of course, under "some balls" we know we have 5 of them and
c1 and c4 are chosen to have none. The problem then becomes: in how many ways can we write 5 has a sum of 2 nonnegative integers? Here, n=5 and k=1.
Case 2 has c1=c4=1 so we have the question: in how many ways can we write 5-2=3 as a sum of 2 nonnegative integers (remaining balls)? Run through all the cases and add them up.
Does this makes sense? Maybe there's a way easier way to solve this but hey, its an idea. What I'm saying is that my strategy would be to consider the actual proof and see what modifications need to be made
answered Jan 22 at 20:49
JayJay
296
$endgroup$
add a comment |
$begingroup$
I haven't done combinatorics in a long time so I might not give you the correct answer but here are some thoughts:
First off, perhaps you should clarify/consider if zeros are allowed. Let's suppose this is so. Think about how your formula can be justified combinatorially: using balls and walls. You can read that here: https://math.dartmouth.edu/archive/m68f09/public_html/m68l02.pdf
I would think of a simpler case. writing 5 as a sum of 4 parts c1, c2, c3 and c4. My idea would then be that we would have 3 cases: c1=c4=0,1 or 2 (3 won't do it). Also notice that I'm using a multiple of 5 for a reason. I guess you would have to take the floor or ceiling function of 75/2.
We're gonna have to use 3 walls (k-1 in your formula). Case 1 looks like this:
$underset{c1}{}|underset{c2}{text{some balls}}|underset{c3}{text{some balls}}|underset{c4}{}$. Of course, under "some balls" we know we have 5 of them and
c1 and c4 are chosen to have none. The problem then becomes: in how many ways can we write 5 has a sum of 2 nonnegative integers? Here, n=5 and k=1.
Case 2 has c1=c4=1 so we have the question: in how many ways can we write 5-2=3 as a sum of 2 nonnegative integers (remaining balls)? Run through all the cases and add them up.
Does this makes sense? Maybe there's a way easier way to solve this but hey, its an idea. What I'm saying is that my strategy would be to consider the actual proof and see what modifications need to be made
answered Jan 22 at 20:49
JayJay
296
$endgroup$
I haven't done combinatorics in a long time so I might not give you the correct answer but here are some thoughts:
First off, perhaps you should clarify/consider if zeros are allowed. Let's suppose this is so. Think about how your formula can be justified combinatorially: using balls and walls. You can read that here: https://math.dartmouth.edu/archive/m68f09/public_html/m68l02.pdf
I would think of a simpler case. writing 5 as a sum of 4 parts c1, c2, c3 and c4. My idea would then be that we would have 3 cases: c1=c4=0,1 or 2 (3 won't do it). Also notice that I'm using a multiple of 5 for a reason. I guess you would have to take the floor or ceiling function of 75/2.
We're gonna have to use 3 walls (k-1 in your formula). Case 1 looks like this:
$underset{c1}{}|underset{c2}{text{some balls}}|underset{c3}{text{some balls}}|underset{c4}{}$. Of course, under "some balls" we know we have 5 of them and
c1 and c4 are chosen to have none. The problem then becomes: in how many ways can we write 5 has a sum of 2 nonnegative integers? Here, n=5 and k=1.
Case 2 has c1=c4=1 so we have the question: in how many ways can we write 5-2=3 as a sum of 2 nonnegative integers (remaining balls)? Run through all the cases and add them up.
Does this makes sense? Maybe there's a way easier way to solve this but hey, its an idea. What I'm saying is that my strategy would be to consider the actual proof and see what modifications need to be made
answered Jan 22 at 20:49
JayJay
296
edited Jan 22 at 20:55
answered Jan 22 at 20:49
JayJay
296
answered Jan 22 at 20:49
JayJay
296
answered Jan 22 at 20:49
JayJay
296
296
add a comment |
add a comment |
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$begingroup$
In your "understanding," what would $n$ and $k$ be for this case? Does your formula work for a simple small case, such as $x_1 + x_2 + x_3 = 5$? And why not simply ask your question: $2 x_1 + x_2 + x_3 + x_4 = 75$?
$endgroup$
– David G. Stork
Jan 22 at 19:30
1
$begingroup$
Think of distributing 75 cookies among five people. Except among those five people there are two brothers who need to receive the same number of cookies! Feel free to ask for any clarifications and I shall help!
$endgroup$
– The Jade Emperor
Jan 22 at 19:36
$begingroup$
To my understanding n = 5 and k = 3.
$endgroup$
– EveresttML
Jan 22 at 19:47