Problem:
Let P(z)=z3+az2+bz+c, where a,b, and c are real. There exists a complex number w such that the three roots of P(z) are w+3i,w+9i, and 2wβ4, where i2=β1. Find β£a+b+cβ£.
Solution:
Let w=x+yi, where x and y are real. Then because a is real and the sum of the three roots is βa, it follows that Im((w+3i)+(w+9i)+(2wβ4))=0. Thus y+3+y+9+2y=0, and y=β3. Therefore the three roots are x,x+6i, and 2xβ4β6i. Because the coefficients of P(z) are real, the non-real roots must occur in conjugate pairs, and so x=2xβ4 and x=4. Thus P(z)=(zβ4)(zβ(4+6i))(zβ(4β6i)) and 1+a+b+c=P(1)= (β3)(β3β6i)(β3+6i)=β135. Thus β£a+b+cβ£=β£β135β1β£=136β. Such a polynomial exists: P(z)=z3β12z2+84zβ208 has the zeros 4,4Β±6i, which satisfy the conditions of the problem for w=4β9i.
The problems on this page are the property of the MAA's American Mathematics Competitions