Suppose f(x) has zeros at x = -3, x = 3, x = 5, and a y-intercept of 17.

In addition, f(x) has the following long-run behavior: as x -> +-infinity, y -> +infinity

Find the formula for the polynomial f(x) which has the minimum possible degree

F(x) = k(x+3)^2(x-3)(x-5)

I cannot find the value for k

since as x ---> ± infinity, y --> + infinitey, the function must be of even exponent, so one of the roots must be a double root, as you have

f(x) = k(x-3)(x+3)(x-5)
but we are also told that the y-intercept is 17, so we have the point (0,17) on our polynomial.

17= k(-3)^2(3)(-5)
17 = -135a
a = -17/135 , so

f(x) = -(17/135)(x-3)^2 (x+3)(x-5)

however, why could the double root not have been the -3 ?
Then
f(x) = a(x+3)^2 (x-3)(x-5)
17 = a(9)(-3)(-5)
17 = 135a
a = 17/135 , and
f(x) = (17/135)(x+3)^2 (x-3)(x-5)

or why not
f(x) = b(x-3)(x+3)(x-5)^2
17 = b(-3)(3)(25)
b = - 17/225

f(x) = -17/225)(x^2 - 9)(x-5)^2

To find the value of k in the polynomial F(x) = k(x+3)^2(x-3)(x-5), we can use the information given about the y-intercept.

At the y-intercept, x = 0. Therefore, we can substitute x = 0 into the polynomial to find the value of y:

F(0) = k(0+3)^2(0-3)(0-5)
= k(3)^2(-3)(-5)
= k(9)(3)(5)
= 135k

We also know that at the y-intercept, y = 17. So, we can set F(0) equal to 17 and solve for k:

17 = 135k

Solving for k, we divide both sides of the equation by 135:

k = 17/135

Therefore, the value of k is 17/135.