What are the possible number of positive, negative, and complex zeros of f(x) = 3x4 - 5x3 - x2 - 8x + 4

Question

richyw · Answer

Ok well first of all it's a quadratic function, so the total will be 4. Use Descartes’ Rule of Signs. Your function is $$p(x)=3x^4-5x^3-x^2-8x+4$$ So count the number of sign changes. A "sign change" is when the sign the coefficient of the $a^n$ is different from the sign of the coefficient of $a^{n-1}$. So here you have one sign changes. You do the same thing for $p(-x)$ and also find one sign change (don't include the sign change for the 4! only the ones that multiply by x matter. Since there must be 4 total you know that it is one positive, one negative and two complex (the complex ones have to be an even number!)

richyw · Answer

sorry not quadratic. haha. 4th degree polynomial

richyw · Answer

or "quartic (I just had to google that, lol)

cruffo · Answer

I thought there were two sign changes.
$$ p(x)=3x^4-5x^3-x^2-8x+4 \rightarrow \color{red}{+}\color{red}{-}- \color{red}- \color{red}+$$

cruffo · Answer

# of possible positive zeros is the number of sigh changes of the polynomial, or less than that number by an even integer.
So the number of possible positive zeros is 2  or 0

richyw · Answer

there is only one sign change though. That last one doesn't matter.

cruffo · Answer

??? http://www.purplemath.com/modules/drofsign.htm

richyw · Answer

weird, I might be wrong. But I don't think so.

cruffo · Answer

Take a look at the graph: http://www.wolframalpha.com/input/?i=p%28x%29%3D3x^4-5x^3-x^2-8x%2B4+from+-3+to+3

richyw · Answer

oh yeah you are totally correct!

richyw · Answer

so in this case using the rule of signs all that you can know is one of four possible combinations then right? Also I have been doing this wrong for like 5 years haha. good thing we have calculators...

cruffo · Answer

: ) Sounds right:
degree 4 means you will find 4 solutions to p(x) = 0
 For this polynomial, just looking at the signs, we can tell that there will be 2 or 0 positive roots, 2 or 0 negative roots.  
For the complex roots - they always come in pairs.  so...
case 1:  2 + real zeros, 0 - real zeros, and 2 complex zeros
case 2:  0 + real zeros, 2 - real zeros, and 2 complex zeros
case 3: 2 + real zeros, 2 - real zeros, and 0 complex zeros
case 4: 0 + real zeros, 0 - real zeros, and 4 complex zeros