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Given that is a factor of evaluate
the sum of the four roots of the equation
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Notice that x^2-3x+2 = (x-2)*(x-1).
We are given that the polynomial x^4 + kx^3 - 10x^2 - 20x+24 is divisible by the polynomial x^2-3x+2 .
Hence, the polynomial x^4 + kx^3 - 10x^2 - 20x+24 is divisible by (x-1).
It means (the Remainder theorem) that the number x= 1 is the root of the polynomial x^4 + kx^3 - 10x^2 - 20x+24.
So, we substitute x= 1 into this polynomial, and we get this equation for "k"
1^4 + k*1^3 - 10*1^2 - 20*1 + 24 = 0,
or
1 + k - 10 - 20 + 24 = 0,
k = 5.
Now use the Vieta's theorem: the sum of the roots of the polynomial x^4 + kx^3 - 10x^2 - 20x + 24 is equal
to the coefficient at x^3 with the opposite sign.
It gives that the sum of the roots of the polynomial x^4 + kx^3 - 10x^2 - 20x+24 is equal to -k, i.e. -5. ANSWER
Solved.
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Given that is a factor of evaluate the sum of the four roots of the equation
When factored, = (x - 1)(x - 2).
As is a factor of , x - 1 and x - 2 are also factors of , which
means that x - 1 = 0, or x = 1, and x - 2 = 0, or x = 2. So, 2 of the roots of are 1 and 2.
Using either root, and the RATIONAL ROOT THEOREM, we find that k = 5.
The equation now becomes: , and when POLYNOMIAL LONG-DIVISION and its
factor, are used, the other factor of the polynomial, is derived.
And, when is factored, its roots, from its factors x + 6 and x + 2, are - 6 and - 2.
We now have roots: 1, 2, - 6, and - 2.
Therefore, the sum of the roots of or = 1 + 2 + (- 6) + (- 2) = - 5.