The sum $sum_{r=0}^{20}r(20-r)binom{20}{r}^2$











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Find the value of: $$displaystyle sum_{r=0}^{20}r(20-r)dbinom{20}{r}^2$$




Attempt:



Using, $dbinom{n}{r}= dfrac n r dbinom{n-1}{r-1}$, I get $400sum_{r=0}^{20}left(dbinom {19} r dbinom{19}{r-1}right)$



What do I do next? I tried to use $dbinom n r +dbinom n {r-1}= dbinom{n+1}{r}$ but that didn't help. Also, I know that the sum of square of binomial coefficients is $dbinom {2n}{n}$ and the Vandermonde's identity is $dbinom{n+m}{r}= sum _{k=0}^r dbinom m k dbinom n {r-k}$.










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    Then you replace $binom{19}{r-1}$ by $binom{19}{20-r}$, and think about some combinatorial arguments comparing your summation and $binom{19+19}{r+(20-r)} = binom{38}{20}$... (You have 19 black balls and 19 white balls, in how many ways can you pick 20 balls...?)
    – Hw Chu
    Feb 28 at 21:14












  • @HwChu Is it equivalent to the number of non negative integer solutions of $x+y = 20$?
    – Abcd
    Feb 28 at 21:25










  • @HwChu I'd like to see the combinatorial solution
    – Abcd
    Feb 28 at 21:30






  • 1




    I wanted to say this is just the Vandermonde's identity. I did not know that identity had a name when I made the comment, so you may just look at the combinarotial proof of Vandermonde's identity.
    – Hw Chu
    Feb 28 at 21:45















up vote
2
down vote

favorite













Find the value of: $$displaystyle sum_{r=0}^{20}r(20-r)dbinom{20}{r}^2$$




Attempt:



Using, $dbinom{n}{r}= dfrac n r dbinom{n-1}{r-1}$, I get $400sum_{r=0}^{20}left(dbinom {19} r dbinom{19}{r-1}right)$



What do I do next? I tried to use $dbinom n r +dbinom n {r-1}= dbinom{n+1}{r}$ but that didn't help. Also, I know that the sum of square of binomial coefficients is $dbinom {2n}{n}$ and the Vandermonde's identity is $dbinom{n+m}{r}= sum _{k=0}^r dbinom m k dbinom n {r-k}$.










share|cite|improve this question




















  • 1




    Then you replace $binom{19}{r-1}$ by $binom{19}{20-r}$, and think about some combinatorial arguments comparing your summation and $binom{19+19}{r+(20-r)} = binom{38}{20}$... (You have 19 black balls and 19 white balls, in how many ways can you pick 20 balls...?)
    – Hw Chu
    Feb 28 at 21:14












  • @HwChu Is it equivalent to the number of non negative integer solutions of $x+y = 20$?
    – Abcd
    Feb 28 at 21:25










  • @HwChu I'd like to see the combinatorial solution
    – Abcd
    Feb 28 at 21:30






  • 1




    I wanted to say this is just the Vandermonde's identity. I did not know that identity had a name when I made the comment, so you may just look at the combinarotial proof of Vandermonde's identity.
    – Hw Chu
    Feb 28 at 21:45













up vote
2
down vote

favorite









up vote
2
down vote

favorite












Find the value of: $$displaystyle sum_{r=0}^{20}r(20-r)dbinom{20}{r}^2$$




Attempt:



Using, $dbinom{n}{r}= dfrac n r dbinom{n-1}{r-1}$, I get $400sum_{r=0}^{20}left(dbinom {19} r dbinom{19}{r-1}right)$



What do I do next? I tried to use $dbinom n r +dbinom n {r-1}= dbinom{n+1}{r}$ but that didn't help. Also, I know that the sum of square of binomial coefficients is $dbinom {2n}{n}$ and the Vandermonde's identity is $dbinom{n+m}{r}= sum _{k=0}^r dbinom m k dbinom n {r-k}$.










share|cite|improve this question
















Find the value of: $$displaystyle sum_{r=0}^{20}r(20-r)dbinom{20}{r}^2$$




Attempt:



Using, $dbinom{n}{r}= dfrac n r dbinom{n-1}{r-1}$, I get $400sum_{r=0}^{20}left(dbinom {19} r dbinom{19}{r-1}right)$



What do I do next? I tried to use $dbinom n r +dbinom n {r-1}= dbinom{n+1}{r}$ but that didn't help. Also, I know that the sum of square of binomial coefficients is $dbinom {2n}{n}$ and the Vandermonde's identity is $dbinom{n+m}{r}= sum _{k=0}^r dbinom m k dbinom n {r-k}$.







combinatorics summation binomial-coefficients binomial-theorem






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edited Nov 16 at 11:51









Martin Sleziak

44.4k7115268




44.4k7115268










asked Feb 28 at 21:08









Abcd

2,88711130




2,88711130








  • 1




    Then you replace $binom{19}{r-1}$ by $binom{19}{20-r}$, and think about some combinatorial arguments comparing your summation and $binom{19+19}{r+(20-r)} = binom{38}{20}$... (You have 19 black balls and 19 white balls, in how many ways can you pick 20 balls...?)
    – Hw Chu
    Feb 28 at 21:14












  • @HwChu Is it equivalent to the number of non negative integer solutions of $x+y = 20$?
    – Abcd
    Feb 28 at 21:25










  • @HwChu I'd like to see the combinatorial solution
    – Abcd
    Feb 28 at 21:30






  • 1




    I wanted to say this is just the Vandermonde's identity. I did not know that identity had a name when I made the comment, so you may just look at the combinarotial proof of Vandermonde's identity.
    – Hw Chu
    Feb 28 at 21:45














  • 1




    Then you replace $binom{19}{r-1}$ by $binom{19}{20-r}$, and think about some combinatorial arguments comparing your summation and $binom{19+19}{r+(20-r)} = binom{38}{20}$... (You have 19 black balls and 19 white balls, in how many ways can you pick 20 balls...?)
    – Hw Chu
    Feb 28 at 21:14












  • @HwChu Is it equivalent to the number of non negative integer solutions of $x+y = 20$?
    – Abcd
    Feb 28 at 21:25










  • @HwChu I'd like to see the combinatorial solution
    – Abcd
    Feb 28 at 21:30






  • 1




    I wanted to say this is just the Vandermonde's identity. I did not know that identity had a name when I made the comment, so you may just look at the combinarotial proof of Vandermonde's identity.
    – Hw Chu
    Feb 28 at 21:45








1




1




Then you replace $binom{19}{r-1}$ by $binom{19}{20-r}$, and think about some combinatorial arguments comparing your summation and $binom{19+19}{r+(20-r)} = binom{38}{20}$... (You have 19 black balls and 19 white balls, in how many ways can you pick 20 balls...?)
– Hw Chu
Feb 28 at 21:14






Then you replace $binom{19}{r-1}$ by $binom{19}{20-r}$, and think about some combinatorial arguments comparing your summation and $binom{19+19}{r+(20-r)} = binom{38}{20}$... (You have 19 black balls and 19 white balls, in how many ways can you pick 20 balls...?)
– Hw Chu
Feb 28 at 21:14














@HwChu Is it equivalent to the number of non negative integer solutions of $x+y = 20$?
– Abcd
Feb 28 at 21:25




@HwChu Is it equivalent to the number of non negative integer solutions of $x+y = 20$?
– Abcd
Feb 28 at 21:25












@HwChu I'd like to see the combinatorial solution
– Abcd
Feb 28 at 21:30




@HwChu I'd like to see the combinatorial solution
– Abcd
Feb 28 at 21:30




1




1




I wanted to say this is just the Vandermonde's identity. I did not know that identity had a name when I made the comment, so you may just look at the combinarotial proof of Vandermonde's identity.
– Hw Chu
Feb 28 at 21:45




I wanted to say this is just the Vandermonde's identity. I did not know that identity had a name when I made the comment, so you may just look at the combinarotial proof of Vandermonde's identity.
– Hw Chu
Feb 28 at 21:45










2 Answers
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Hint: Write the sum as $$sum_{r=0}^{20}left(rbinom{20}{r}right)cdotleft((20-r)binom{20}{20-r}right) = sum_{r = 0}^{20}a_ra_{20-r},$$
where $a_r = rbinom{20}{r}.$ This is the coefficient of $x^{20}$ in the expansion of $$left(sum_{r=0}^{20}a_rx^rright)^2.$$






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    $$sum_{r=0}^{20} r(20-r)binom {20}{r} ^2=20sum_{r=0}^{20} rbinom {20}{r} ^2- sum_{r=0}^{20} r^2binom {20}{r} ^2=400sum_{r=1}^{20} binom {19}{r-1}binom {20}{20-r} - 400sum_{r=1}^{20} binom {19}{r-1}binom {19}{19-(r-1)}$$



    Hence by Vandermonde's identity we get $$400left(sum_{r=1}^{20} binom {19}{r-1}binom {20}{20-r} - sum_{r=1}^{20} binom {19}{r-1}binom {19}{19-(r-1)}right) =400left(binom {39}{19}- binom {38}{19}right) $$



    Now by Pascal's rule $$400left(binom {39}{19}- binom {38}{19}right) =400binom {38}{18}$$



    Alternatively you can reach answer by your way too



    $$400sum_{color{red}{r=1}}^{color{red}{19}} binom {19}{r}binom {19}{20-r}$$



    Hence by using Vandermonde's identity we get $$400sum_{r=1}^{19} binom {19}{r}binom {19}{20-r}=400binom {38}{20}=400binom {38}{18}$$






    share|cite|improve this answer























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      2 Answers
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      2 Answers
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      Hint: Write the sum as $$sum_{r=0}^{20}left(rbinom{20}{r}right)cdotleft((20-r)binom{20}{20-r}right) = sum_{r = 0}^{20}a_ra_{20-r},$$
      where $a_r = rbinom{20}{r}.$ This is the coefficient of $x^{20}$ in the expansion of $$left(sum_{r=0}^{20}a_rx^rright)^2.$$






      share|cite|improve this answer



























        up vote
        2
        down vote













        Hint: Write the sum as $$sum_{r=0}^{20}left(rbinom{20}{r}right)cdotleft((20-r)binom{20}{20-r}right) = sum_{r = 0}^{20}a_ra_{20-r},$$
        where $a_r = rbinom{20}{r}.$ This is the coefficient of $x^{20}$ in the expansion of $$left(sum_{r=0}^{20}a_rx^rright)^2.$$






        share|cite|improve this answer

























          up vote
          2
          down vote










          up vote
          2
          down vote









          Hint: Write the sum as $$sum_{r=0}^{20}left(rbinom{20}{r}right)cdotleft((20-r)binom{20}{20-r}right) = sum_{r = 0}^{20}a_ra_{20-r},$$
          where $a_r = rbinom{20}{r}.$ This is the coefficient of $x^{20}$ in the expansion of $$left(sum_{r=0}^{20}a_rx^rright)^2.$$






          share|cite|improve this answer














          Hint: Write the sum as $$sum_{r=0}^{20}left(rbinom{20}{r}right)cdotleft((20-r)binom{20}{20-r}right) = sum_{r = 0}^{20}a_ra_{20-r},$$
          where $a_r = rbinom{20}{r}.$ This is the coefficient of $x^{20}$ in the expansion of $$left(sum_{r=0}^{20}a_rx^rright)^2.$$







          share|cite|improve this answer














          share|cite|improve this answer



          share|cite|improve this answer








          edited Feb 28 at 22:20

























          answered Feb 28 at 21:21









          dezdichado

          5,7321928




          5,7321928






















              up vote
              0
              down vote













              $$sum_{r=0}^{20} r(20-r)binom {20}{r} ^2=20sum_{r=0}^{20} rbinom {20}{r} ^2- sum_{r=0}^{20} r^2binom {20}{r} ^2=400sum_{r=1}^{20} binom {19}{r-1}binom {20}{20-r} - 400sum_{r=1}^{20} binom {19}{r-1}binom {19}{19-(r-1)}$$



              Hence by Vandermonde's identity we get $$400left(sum_{r=1}^{20} binom {19}{r-1}binom {20}{20-r} - sum_{r=1}^{20} binom {19}{r-1}binom {19}{19-(r-1)}right) =400left(binom {39}{19}- binom {38}{19}right) $$



              Now by Pascal's rule $$400left(binom {39}{19}- binom {38}{19}right) =400binom {38}{18}$$



              Alternatively you can reach answer by your way too



              $$400sum_{color{red}{r=1}}^{color{red}{19}} binom {19}{r}binom {19}{20-r}$$



              Hence by using Vandermonde's identity we get $$400sum_{r=1}^{19} binom {19}{r}binom {19}{20-r}=400binom {38}{20}=400binom {38}{18}$$






              share|cite|improve this answer



























                up vote
                0
                down vote













                $$sum_{r=0}^{20} r(20-r)binom {20}{r} ^2=20sum_{r=0}^{20} rbinom {20}{r} ^2- sum_{r=0}^{20} r^2binom {20}{r} ^2=400sum_{r=1}^{20} binom {19}{r-1}binom {20}{20-r} - 400sum_{r=1}^{20} binom {19}{r-1}binom {19}{19-(r-1)}$$



                Hence by Vandermonde's identity we get $$400left(sum_{r=1}^{20} binom {19}{r-1}binom {20}{20-r} - sum_{r=1}^{20} binom {19}{r-1}binom {19}{19-(r-1)}right) =400left(binom {39}{19}- binom {38}{19}right) $$



                Now by Pascal's rule $$400left(binom {39}{19}- binom {38}{19}right) =400binom {38}{18}$$



                Alternatively you can reach answer by your way too



                $$400sum_{color{red}{r=1}}^{color{red}{19}} binom {19}{r}binom {19}{20-r}$$



                Hence by using Vandermonde's identity we get $$400sum_{r=1}^{19} binom {19}{r}binom {19}{20-r}=400binom {38}{20}=400binom {38}{18}$$






                share|cite|improve this answer

























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                  up vote
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                  down vote









                  $$sum_{r=0}^{20} r(20-r)binom {20}{r} ^2=20sum_{r=0}^{20} rbinom {20}{r} ^2- sum_{r=0}^{20} r^2binom {20}{r} ^2=400sum_{r=1}^{20} binom {19}{r-1}binom {20}{20-r} - 400sum_{r=1}^{20} binom {19}{r-1}binom {19}{19-(r-1)}$$



                  Hence by Vandermonde's identity we get $$400left(sum_{r=1}^{20} binom {19}{r-1}binom {20}{20-r} - sum_{r=1}^{20} binom {19}{r-1}binom {19}{19-(r-1)}right) =400left(binom {39}{19}- binom {38}{19}right) $$



                  Now by Pascal's rule $$400left(binom {39}{19}- binom {38}{19}right) =400binom {38}{18}$$



                  Alternatively you can reach answer by your way too



                  $$400sum_{color{red}{r=1}}^{color{red}{19}} binom {19}{r}binom {19}{20-r}$$



                  Hence by using Vandermonde's identity we get $$400sum_{r=1}^{19} binom {19}{r}binom {19}{20-r}=400binom {38}{20}=400binom {38}{18}$$






                  share|cite|improve this answer














                  $$sum_{r=0}^{20} r(20-r)binom {20}{r} ^2=20sum_{r=0}^{20} rbinom {20}{r} ^2- sum_{r=0}^{20} r^2binom {20}{r} ^2=400sum_{r=1}^{20} binom {19}{r-1}binom {20}{20-r} - 400sum_{r=1}^{20} binom {19}{r-1}binom {19}{19-(r-1)}$$



                  Hence by Vandermonde's identity we get $$400left(sum_{r=1}^{20} binom {19}{r-1}binom {20}{20-r} - sum_{r=1}^{20} binom {19}{r-1}binom {19}{19-(r-1)}right) =400left(binom {39}{19}- binom {38}{19}right) $$



                  Now by Pascal's rule $$400left(binom {39}{19}- binom {38}{19}right) =400binom {38}{18}$$



                  Alternatively you can reach answer by your way too



                  $$400sum_{color{red}{r=1}}^{color{red}{19}} binom {19}{r}binom {19}{20-r}$$



                  Hence by using Vandermonde's identity we get $$400sum_{r=1}^{19} binom {19}{r}binom {19}{20-r}=400binom {38}{20}=400binom {38}{18}$$







                  share|cite|improve this answer














                  share|cite|improve this answer



                  share|cite|improve this answer








                  edited Mar 7 at 17:13

























                  answered Mar 7 at 16:51









                  Digamma

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