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Prove: we always have at least one x>0 is a $x^3+bx^2+cx-d^2=0$ 's root (b, c, d are real numbers and $d≠0$)

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    Use Descartes' rule of signs.2012-11-10

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The statement you mentioned does not hold when d is allowed to be zero. Consider $x^3$ as a counterexample.I will assume that d is different from zeroLet p(x) be the polynomial.thus p(0)<0. Since p(x) tends to infinity as x goes to infinity. Therefore there exists r>0 such that p(r)>0. Now apply the intermediate value theorem on the interval [0,r]

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Let, $p(x) = x^3 + bx^2 + cx - d^2$ Then we have, $p(0)= -d^2 < 0$ We know that there exists $x > 0$ so that: $x^3 > bx^2 + cx - d^2$ For any set of constants $b, c, d$. Let's call this pont $r$. Thus, we know that $p(0) < 0$ and $p(r)>0$ and that $r > 0$.

You can continue the rest.

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If $f(x)=x^3+bx^2+cx-d^2$,

using this, there is only one change of sign in $f(x),$ so $f(x)$ can have at most one positive real root and the number of positive real root will be exactly one as the number of positive roots of the polynomial=the number of sign changes$(m)-2\cdot n$, where $0\le 2n\le m$.