you are the manager of a forest products company with land recently planted (t=0) whith a fast-growing species of a pine. the merchantable volume of timber at instant t>0 is given by v(t) =10t+t^-0.01t°

a. To find the maximum volume and when it occurs, we need to find the maximum of the given function v(t) = 10t + t^(-0.01t°).

To do this, we can take the derivative of v(t) with respect to t and set it equal to zero:

dv(t)/dt = 10 - 0.01t°(-0.01t° - 1) = 0

Simplifying this equation:

10 - 0.01t°(-0.01t° - 1) = 0
10 - 0.01t°(-0.01t° - 1) = 0
10 - 0.01t(-0.01t - 1) = 0
10 - 0.0001t² - 0.01t = 0
0.0001t² + 0.01t - 10 = 0

We can solve this quadratic equation for t, either by factoring, completing the square, or using the quadratic formula. Let's use the quadratic formula:

t = (-0.01 ± √(0.01² - 4 * 0.0001 * (-10))) / (2 * 0.0001)
t = (-0.01 ± √(0.0001 + 0.004)) / 0.0002
t ≈ (-0.01 ± √0.0041) / 0.0002

Since we are interested in t > 0, we can ignore the negative value.

t ≈ (-0.01 + √0.0041) / 0.0002
t ≈ (-0.01 + 0.064) / 0.0002
t ≈ 0.054 / 0.0002
t ≈ 270

The maximum volume occurs at t = 270, and the maximum volume is v(270) = 10(270) + (270^(-0.01(270°))) = 2700 + (270^(-2.7)).

b. To find the harvest time that maximizes mean annual increment [v(t)/t], we need to find the maximum of the function [v(t)/t].

We can rewrite the function [v(t)/t] as [10t/t + t^(-0.01t°)/t]:

[v(t)/t] = 10 + t^(-0.01t°-1)

To find the maximum, we need to take the derivative of [v(t)/t] with respect to t and set it equal to zero:

d[v(t)/t]/dt = -0.01t°(-0.01t° - 1) = 0

Simplifying this equation:

-0.01t°(-0.01t° - 1) = 0
-0.01t(-0.01t - 1) = 0
-0.0001t² - 0.01t = 0
t(-0.0001t - 0.01) = 0

This equation has two solutions: t = 0 and t ≈ -100. Since we are interested in t > 0, we can ignore the t = 0 solution.

Therefore, the harvest time that maximizes mean annual increment is t ≈ -100.

To find the associated volume, we can substitute this value into the original volume function:

v(-100) = 10(-100) + (-100)^(-0.01(-100°))
v(-100) = -1000 + (-100)^(-10)
(Note: Since the given volume function is not defined for negative values of t, the result might not be meaningful.)

c. To find the optimal harvest time, we need to consider the present value of net benefits (PVNB) at t=0.

The present value of net benefits is given as:

PVNB = ∫[v(t)*(1+r)^(-t)]dt

Substituting the given volume function into the integral:

PVNB = ∫[(10t + t^(-0.01t°))*(1+0.05)^(-t)]dt

To find the optimal harvest time, we need to maximize this integral. This can be done using numerical methods such as integration techniques or optimization algorithms.

Once the optimal harvest time is found, we can determine the volume at that time by substituting the value of t into the volume function v(t).

Note: Without specific values for t or additional information, it is not possible to provide the exact optimal harvest time, volume at optimal harvest time, or present value of NB at t=0.