BINOMIAL THEOREM. 347
The greatest value of 7 consistent with this is 5; hence the greatest term is the sixth, and its value
418. Sum of the Coefficients. To jind the sum of the coefficients in the expansion of (1+x)n.
In the identity
(1+x)n=1+4 Ga + Ca? + Cr? + --- + Ca";
put x=1; thus 2=14+ G4 Q+++-+C, = sum of the coefficients.
Cor. Q4+O4+ G4+--4+¢,=27-1; that is, the total number of combinations of n things taking some or all of them at a time is 2n —1. [See Art. 400.]
419. Sums of Coefficients equal. To prove that in the expansion of (1+x)n, the sum of the coefficients of the odd terms is equal to the sum of the coefficients of the even terms.
In the identity
+a)" =1+ Cy + Cy? + Cy? + --- + C2’, put x=—1; thus 0=1-G4+6-G4+¢6,-C6,4+--; ~14646,4+--=O4+0,4+6,+---.
420. Expansion of Multinomials. The Binomial Theorem may also be applied to expand expressions which contain more than two terms.
Ex. Find the expansion of (x2+2x-1)3.
Regarding 2x-1 as a single term, the expansion
= (x2)3 + 3(x2)2(2x-1)+3x2(2a-1)2 +(2x-1)3 = x6 + 6x5 +9x4 -4x3 - 9x2+ 6x -1, on reduction.
421. Binomial Theorem for Negative or Fractional Index. For a full discussion of the Binomial Theorem when the index is not restricted to positive integral values the student