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| Integer coefficients (Posted on 2007-03-13) |
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Determine if it is possible that p(x)*q(x)= x5+9x+1, if p(x) and q(x) must be polynomials of degree 1 or higher, with integer coefficients.
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Submitted by K Sengupta
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Solution:
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Clearly, the only possible integer roots of the polynomial x^5 + 9x +1 are +/- 1 and these are not zeroes of this polynomial, it follows that it has no linear factors.
Accordingly, we express x^5 + 9x +1 = p(x)*q(x); where p(x) is of degree 2 and q(x) is of degree 3.
Since the coefficient of x^0 in the given polynomial is 1, we can assume without loss of generality p(x) = x^2 + a*x +b and q(x) = x^3 + c*x^2 + d*x +e.
Accordingly, be=1, so that :
(b,e) =(1,1) or (-1,-1).
Case I: b=e=1
Comparing the coefficients of x, we obtain ae + bd=9; that is, a+d=9-------(1)
Also, comparing the coefficients of x^4 and x^3, we obtain:
a+c=0 giving a=-c and, b+ac+d = 0; or, b+d=a^2; or a^2 = d+1.----------(2)
From (1) and (2), we obtain: a^2 -1 + a = 9; giving, a^2 + a -10 = 0. This equation does not admit of any integer roots, and this is accordingly, a contradiction.
Case II: b=e=-1.
Hence, a+d=-9; b+d = a^2 and a^2 = d-1
Therefore, a + a^2 + 1 = -9; giving, a^2 + a + 10 = 0, which does not possess any integer roots. This is a contradiction.
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Consequently, there cannot exist polynomials p(x) and q(x) each having integer coefficients and of degree greater than or equal to 1 such that:
p(x)*q(x)= x^5 + 9x +1.
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