The size P of a certain insect population at time t​ (in days) obeys the function...

Exercise 1.3.52: Let P(t) be the population of a certain species of insect at time t,...

Exercise 1.3.52: Let P(t) be the population of a certain species of insect at time t, where t is measured in days. Suppose a population of 30,000 insects grows to 150,000 in 3 days. a) Find the growth constant for this population. b) Write the corresponding initial value problem (DE and IC) and its solution. c) How long will it take for the population to triple?

A population of insects increases at a rate of 240+12t+0.3t^2 insects per day. Find the insect...

A population of insects increases at a rate of 240+12t+0.3t^2 insects per day. Find the insect population after 5 days, assuming that there are 70 insects t=0.

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.

A species of fish was added to a lake. The population size P (t) of this...

A species of fish was added to a lake. The population size P (t) of this species can be modeled by the following exponential function, where t is the number of years from the time the species was added to the lake.P (t) =1000/(1+9e^0.42t) Find the initial population size of the species and the population size after 9 years. Round your answer to the nearest whole number as necessary. Initial population size is : Population size after 9 years is:

The population, P, of a small town is modelled by the function P(t)=-2t3+55t2+15t+22000 , where t=0...

The population, P, of a small town is modelled by the function P(t)=-2t3+55t2+15t+22000 , where t=0 represents the beginning of this year. a) What is the initial population? b) What is the population at the end of 10 years? c) What is the average rate of change over 10 years? d) Estimate the instantaneous rate of change at the end of the10th year. e) What is the difference between your answer in b) and d)?

Exponential Model: P(t) = M(1 − e^−kt) where M is maximum population. Logistic Model: P (t)...

Exponential Model: P(t) = M(1 − e^−kt) where M is maximum population. Logistic Model: P (t) = M / 1+Be^−MKt where M is maximum population. Scientists study a fruit fly population in the lab. They estimate that their container can hold a maximum of 500 flies. Seven days after they start their experiment, they count 250 flies. 1. (a) Use the exponential model to find a function P(t) for the number of flies t days after the start of the...

If a bacteria population starts with 125 bacteria and doubles in size every half hour, then...

If a bacteria population starts with 125 bacteria and doubles in size every half hour, then the number of bacteria after t hours is n = f(t) = 125 · 4t. (a) Find the inverse of this function. t =  log4​(t125​)    Explain its meaning. a The inverse function gives the population after half an hour has passed. b The inverse function gives the population after 4 hours have passed.      c The inverse function gives the number of hours that have...

The rate of growth dP/dt of a population of bacteria is proportional to the square root...

The rate of growth dP/dt of a population of bacteria is proportional to the square root of t with a constant coefficient of 7, where P is the population size and t is the time in days (0≤t≤10). The initial size of the population is 600. Approximate the population after 7 days. Round the answer to the nearest integer.

A bacterial population starts with 10,000 bacteria and grows at a rate proportional to its size....

A bacterial population starts with 10,000 bacteria and grows at a rate proportional to its size. After 2 hours there are 40,000 bacteria. a) Find the growth rate k. Round k to 3 decimal places. b) Find the number of bacteria after 5 hours. c) When will the population reach 1 million? d) What is the doubling time?

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?