Suppose n=10,r=3,then i want to find the sum of the products of numbers taken 3 at a time from 1 to 10 and all the combinations considered.There will be nCr possible products and i want their sum.
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1Can you provide an example? "products of numbers taken 3 at a time" is a bit vague.– Scott HunterFeb 3, 2016 at 19:42
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1This question is more suitable for math.stackexchange.com. Also, you should show some effort to solve the problem yourself; people won't want to help you if it looks like you just want them to give you the answer.– Robert DodierFeb 3, 2016 at 20:04
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@ScottHunter suppose n=4 and r=2,then I want to find: [1.2+1.3+1.4+1.5+2.3+2.4+2.5+3.4+3.5+4.5] i.e. sum of all product combinations of first 5 natural numbers taken 2 at a time– Gaurav SinglaFeb 4, 2016 at 5:58
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@RobertDodier I tried this problem for hours by myself and when I couldn't solve only then I asked it here.– Gaurav SinglaFeb 4, 2016 at 6:01
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@RobertDodier I tried this problem for hours by myself and when I couldn't solve only then I asked it here.– Gaurav SinglaFeb 4, 2016 at 6:07
2 Answers
What you want is the degree 7 coefficient of
(x+1)(x+2)·…·(x+10)
You can compute all coefficients of that polynomial in O(n²) operations by adding one factor after the other.
For the computation of coefficients from roots see How to efficiently find coefficients of a polynomial from its roots?, Efficient calculation of polynomial coefficients from its roots, Find the coefficients of the polynomial given its roots
A recurrence for S(n, m)
where S
is the sum you want is: S(n + 1, m) = S(n, m) + (n + 1)*S(n, m - 1)
, with S(n, 1) = n*(n + 1)/2
and S(m, m) = m!
.
The term (n + 1)*S(n, m - 1)
comes from the additional terms in the sum which are created by increasing n
by 1: these terms are all the ones you get for S(n, m - 1)
(i.e. take one fewer term in the product) and append n + 1
to each one.
I don't know how to solve recurrences like that in general. In this case, I would build a table of terms S(n, m)
which would look like a triangle. The bottom row would be for S(n, 1)
which is n*(n + 1)/2
. The diagonal would be S(m, m)
which is m!
. So you could try to guess a formula which gives general entries in the table and then add them all up.
A Python program to compute S(n, m)
for specific values of n
and m
might look like:
import math
def S(n, m):
if m == 1:
return n*(n + 1)/2
elif n == m:
return math.factorial(m)
else:
return S(n - 1, m) + n*S(n - 1, m - 1)
which requires, I believe, approximately m*n
unique calls to S
(but there are many duplicates). Of course it's easy to write this in some other language.
For example, S(10, 3) = 18150
.
EDIT: revised the estimated number of operations.