a logistic equation for a pipulation P(T) in which there is harvesting can be written as...

Suppose that the population develops according to the logistic equation dP/dt = 0.0102P - 0.00003P^2 where...

Suppose that the population develops according to the logistic equation dP/dt = 0.0102P - 0.00003P^2 where t is measured in days. What is the P value after 10 days where A = (M-P(0)) / P(0)) if the P(0) = 40? And P(0) = 20?

A population P obeys the logistic model. It satisfies the equation dP/dt=(2/700)*P(7−P) for P>0 Assume that...

A population P obeys the logistic model. It satisfies the equation dP/dt=(2/700)*P(7−P) for P>0 Assume that P(0)=2. Find P(53)

Logistic Equation The logistic differential equation y′=y(1−y) appears often in problems such as population modeling. (a)...

Logistic Equation The logistic differential equation y′=y(1−y) appears often in problems such as population modeling. (a) Graph the slope field of the differential equation between y= 0 and y= 1. Does the slope depend on t? (b) Suppose f is a solution to the initial value problem with f(0) = 1/2. Using the slope field, what can we say about fast→∞? What can we say about fast→−∞? (c) Verify that f(t) =11 +e−tis a solution to the initial value problem...

Differential Equations problem Given the equation - dP / dt = kP(M - P) - h...

Differential Equations problem Given the equation - dP / dt = kP(M - P) - h where k, h, and M are constant real numbers and P is population as a function of time t, with the initial condition P(0) = Po, find the solution for P(t). Show your work and enough steps so another student can understand the solution.

Suppose that a population develops according to the following logistic population model. dp/dt=0.04p-0.0001p^2 What is the...

Suppose that a population develops according to the following logistic population model. dp/dt=0.04p-0.0001p^2 What is the carrying capacity? 0.0001 400 10000 0.04 0.0025 What are the equilibrium solutions for the population model ? P = 400 only P = 0 and P = 10000 P = 0 and P = 400 P = 0 only Using the population model , for what values of P  is the population increasing? (0,400) and (0,10000) and

The population P(t) of bacteria grows according to the logistics equation dP/dt=P(12−P/4000), where t is in...

The population P(t) of bacteria grows according to the logistics equation dP/dt=P(12−P/4000), where t is in hours. It is known that P(0)=700. (1) What is the carrying capacity of the model? (2) What is the size of the bacteria population when it is having is fastest growth?

Assuming that P≥0, a population is modeled by the differential equation dP/dt = 1.4P(1- P/3400) 1....

Assuming that P≥0, a population is modeled by the differential equation dP/dt = 1.4P(1- P/3400) 1. For what values of P is the population increasing? Answer (in interval notation): 2. For what values of P is the population decreasing? Answer (in interval notation): 3. What are the equilibrium solutions? Answer (separate by commas): P =

The population of the world was about 5.3 billion in 1990 (t = 0) and about...

The population of the world was about 5.3 billion in 1990 (t = 0) and about 6.1 billion in 2000 (t = 10). Assuming that the carrying capacity for the world population is 50 billion, the logistic differential equation dP =kP(50−P)dt models the population of the world P(t) (measured in billions), where t is the number of years after 1990. Solve this differential equation for P(t) and use this solution to predict what the population will be in 2050 according...

Find the solution to the following equation for an age-structured population: ∂/∂t P(t,a)+ ∂/∂a P(t,a)=−δ(a)P(t,a), a≥0,t≥0...

Find the solution to the following equation for an age-structured population: ∂/∂t P(t,a)+ ∂/∂a P(t,a)=−δ(a)P(t,a), a≥0,t≥0 P(0,a) = P0(a) P(t,0) = C where C > 0 is a constant. Bonus: What is the asymptotic behavior of the population (total size, age-distribution if possible) as t → ∞? If limit exists, is it a solution to the PDE and, if so, what kind of solution?     

Suppose that the certain population obeys the logistics equation dP / dt = 0.025·P ·(1−P /...

Suppose that the certain population obeys the logistics equation dP / dt = 0.025·P ·(1−P / C) where C is the carrying capacity. If the initial population P0 = C/3, find the time t∗ at which the initial population has doubled, i.e., find time t∗ such that P(t∗) = 2P0 = 2C/3.