Use the Intermediate Value Theorem to show that each polynomia...

Question

Use the Intermediate Value Theorem to show that each polynomial has a real zero between the given integers.f(x)=2x⁴−4x²+1; between -1 and 0

Accepted Answer

Hello. Today we are going to be using the intermediate value theorem to determine whether the polynomial F of X has a real zero between negative two and one. Before we jump into this problem, let's quickly review what the intermediate value theorem states. So let's suppose that we have some random function F of X and F of X is bounded between the values of A and B notice that at the boundary A F of X is negative and at the boundary BF of X is positive. So what the intermediate value theorem states is that if the bound values of the boundaries are negative and positive or vice versa, then the graph F of X must cross the X axis at least one point at one point, meaning that there exists at least one real root for the given polynomial. So let's take a look at the polynomial. We are told that F of X is equal to five X to the fourth power minus nine X squared minus 19. And we want to determine if this has a real root on the boundary from negative 2 to 1. In order to start this problem, we are going to take the values of our boundaries and plug it in to F of X. If we see that the value of one boundary is negative and the value of the other is positive or vice versa, then that tells us that there exists at least one real route for the polynomial. So in order to start this problem, let's take the value of negative two and plug it into F of X. This will give us F of negative two is equal to five multiplied by negative two to the fourth power minus nine, multiplied by negative two squared minus 19. What we need to do now is we need to simplify negative two race to the fourth power will simplify to positive 16 and negative two squared will simplify to positive four. The first term will be five multiplied by 16 which will leave us with positive 80. For the second term negative nine multiplied by four will give us negative 36. And we have the constant at the end which is negative 19. Finally, 80 minus 36 minus 19 will give us the value of positive 25. So what this tells us is that the value F of negative two is greater than zero, meaning that it is positive. Now, we are going to repeat this process but with the opposite boundary positive one. So if we plug in one to F of X, we get F of one is equal to five multiplied by one to the fourth power minus nine multiplied by one squared minus 19. One race to any power will simplify to just be one that will leave us with the first term which is five multiplied by one, which gives us positive five. The second term negative nine multiplied by one, which is negative nine minus the final term which is negative 19 5 minus nine minus 19 gives us the value of negative 23. So what this tells us is that the value F of one is negative and is less than zero. And since we have opposite values at both of the boundaries given to us, that means that there exists at least one real route for the polynomial F of X. And with that being said, the solution to this problem is going to be a. So I hope this video helps you in understanding how to use the intermediate value theorem. And I'll go ahead and see you all in the next video.

Use the Intermediate Value Theorem to show that each polynomial has a real zero between the given integers.f(x)=2x⁴−4x²+1; between -1 and 0

Key Concepts

Intermediate Value Theorem

Polynomial Continuity

Evaluating Function Values at Interval Endpoints

Watch next

Use the Intermediate Value Theorem to show that each polynomial has a real zero between the given integers.f(x)=2x4−4x2+1; between -1 and 0

Key Concepts

Intermediate Value Theorem

Polynomial Continuity

Evaluating Function Values at Interval Endpoints

Watch next

Use the Intermediate Value Theorem to show that each polynomial has a real zero between the given integers.f(x)=2x⁴−4x²+1; between -1 and 0