imported>Paul Wormer |
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| ==Reference== | | ==Reference== |
| D. E. Kuth, ''The Art of Computer Programming'', Vol I. Addison-Wesley, Reading Mass (1968) p. 64 | | D. E. Knuth, ''The Art of Computer Programming'', Vol I. Addison-Wesley, Reading Mass (1968) p. 64 |
Revision as of 05:50, 22 January 2009
In discrete mathematics, the multinomial coefficient arises as a generalization of the binomial coefficient.
Let k1, k2, ..., km be natural numbers giving a partition of n:
The multinomial coefficient is defined by
For m = 2 we may write:
so that
It follows that the multinomial coefficient is equal to the binomial coefficient for the partition of n into two integer numbers. However, the two coefficients (binomial and multinomial) are notated somewhat differently for m = 2.
The multinomial coefficients arise in the multinomial expansion
The number of terms in this expansion is equal to the binomial coefficient:
Example. Expand (x + y + z)4:
The 15 terms are the following:
A multinomial coefficient can be expressed in terms of binomial coefficients:
Reference
D. E. Knuth, The Art of Computer Programming, Vol I. Addison-Wesley, Reading Mass (1968) p. 64