Get answer: In each of 26 through 33 draw a direction field for the given differential

In each of Problems 1 through 6 draw a direction field for the given differential equation. Based on the direction field, determine the behavior of y as t . If this behavior depends on the initial value of y at t = 0, describe the dependency.y = 3 2y

In each of Problems 1 through 6 draw a direction field for the given differential equation. Based on the direction field, determine the behavior of y as t . If this behavior depends on the initial value of y at t = 0, describe the dependency.y = 2y 3

In each of Problems 1 through 6 draw a direction field for the given differential equation. Based on the direction field, determine the behavior of y as t . If this behavior depends on the initial value of y at t = 0, describe the dependency.y = 3 + 2y

In each of Problems 1 through 6 draw a direction field for the given differential equation. Based on the direction field, determine the behavior of y as t . If this behavior depends on the initial value of y at t = 0, describe the dependency.y = 1 2y

In each of Problems 1 through 6 draw a direction field for the given differential equation. Based on the direction field, determine the behavior of y as t . If this behavior depends on the initial value of y at t = 0, describe the dependency.y = 1 + 2y

In each of Problems 1 through 6 draw a direction field for the given differential equation. Based on the direction field, determine the behavior of y as t . If this behavior depends on the initial value of y at t = 0, describe the dependency.y = y + 2

In each of Problems 7 through 10 write down a differential equation of the form dy/dt = ay + b whose solutions have the required behavior as t .All solutions approach y = 3.

In each of Problems 7 through 10 write down a differential equation of the form dy/dt = ay + b whose solutions have the required behavior as t .All solutions approach y = 2/3

In each of Problems 7 through 10 write down a differential equation of the form dy/dt = ay + b whose solutions have the required behavior as t .

In each of Problems 7 through 10 write down a differential equation of the form dy/dt = ay + b whose solutions have the required behavior as t .All other solutions diverge from y = 2.All other solutions diverge from y = 1/3.

In each of Problems 11 through 14 draw a direction field for the given differential equation. Based on the direction field, determine the behavior of y as t . If this behavior depends on the initial value of y at t = 0, describe this dependency. Note that in these problems the equations are not of the form y = ay + b, and the behavior of their solutions is somewhat more complicated than for the equations in the text.y = y(4 y)

In each of Problems 11 through 14 draw a direction field for the given differential equation. Based on the direction field, determine the behavior of y as t . If this behavior depends on the initial value of y at t = 0, describe this dependency. Note that in these problems the equations are not of the form y = ay + b, and the behavior of their solutions is somewhat more complicated than for the equations in the text.

In each of Problems 11 through 14 draw a direction field for the given differential equation. Based on the direction field, determine the behavior of y as t . If this behavior depends on the initial value of y at t = 0, describe this dependency. Note that in these problems the equations are not of the form y = ay + b, and the behavior of their solutions is somewhat more complicated than for the equations in the text.

In each of Problems 11 through 14 draw a direction field for the given differential equation. Based on the direction field, determine the behavior of y as t . If this behavior depends on the initial value of y at t = 0, describe this dependency. Note that in these problems the equations are not of the form y = ay + b, and the behavior of their solutions is somewhat more complicated than for the equations in the text.y = y(y 2)2

Consider the following list of differential equations, some of which produced the direction fields shown in Figures 1.1.5 through 1.1.10. In each of Problems 15 through 20 identify the differential equation that corresponds to the given direction field.(a) y = 2y 1 (b) y = 2 + y (c) y = y 2 (d) y = y(y + 3) (e) y = y(y 3) (f) y = 1 + 2y (g) y = 2 y (h) y = y(3 y) (i) y = 1 2y (j) y = 2 y

Consider the following list of differential equations, some of which produced the direction fields shown in Figures 1.1.5 through 1.1.10. In each of Problems 15 through 20 identify the differential equation that corresponds to the given direction field.(a) y = 2y 1 (b) y = 2 + y (c) y = y 2 (d) y = y(y + 3) (e) y = y(y 3) (f) y = 1 + 2y (g) y = 2 y (h) y = y(3 y) (i) y = 1 2y (j) y = 2 y

Consider the following list of differential equations, some of which produced the direction fields shown in Figures 1.1.5 through 1.1.10. In each of Problems 15 through 20 identify the differential equation that corresponds to the given direction field.(a) y = 2y 1 (b) y = 2 + y (c) y = y 2 (d) y = y(y + 3) (e) y = y(y 3) (f) y = 1 + 2y (g) y = 2 y (h) y = y(3 y) (i) y = 1 2y (j) y = 2 y

Consider the following list of differential equations, some of which produced the direction fields shown in Figures 1.1.5 through 1.1.10. In each of Problems 15 through 20 identify the differential equation that corresponds to the given direction field.(a) y = 2y 1 (b) y = 2 + y (c) y = y 2 (d) y = y(y + 3) (e) y = y(y 3) (f) y = 1 + 2y (g) y = 2 y (h) y = y(3 y) (i) y = 1 2y (j) y = 2 y

Consider the following list of differential equations, some of which produced the direction fields shown in Figures 1.1.5 through 1.1.10. In each of Problems 15 through 20 identify the differential equation that corresponds to the given direction field.(a) y = 2y 1 (b) y = 2 + y (c) y = y 2 (d) y = y(y + 3) (e) y = y(y 3) (f) y = 1 + 2y (g) y = 2 y (h) y = y(3 y) (i) y = 1 2y (j) y = 2 y

Consider the following list of differential equations, some of which produced the direction fields shown in Figures 1.1.5 through 1.1.10. In each of Problems 15 through 20 identify the differential equation that corresponds to the given direction field.(a) y = 2y 1 (b) y = 2 + y (c) y = y 2 (d) y = y(y + 3) (e) y = y(y 3) (f) y = 1 + 2y (g) y = 2 y (h) y = y(3 y) (i) y = 1 2y (j) y = 2 y

A pond initially contains 1,000,000 gal of water and an unknown amount of an undesirable chemical. Water containing 0.01 g of this chemical per gallon flows into the pond at a rate of 300 gal/h. The mixture flows out at the same rate, so the amount of water in the pond remains constant. Assume that the chemical is uniformly distributed throughout the pond. (a) Write a differential equation for the amount of chemical in the pond at any time. (b) How much of the chemical will be in the pond after a very long time? Does this limiting amount depend on the amount that was present initially?

A spherical raindrop evaporates at a rate proportional to its surface area. Write a differential equation for the volume of the raindrop as a function of time.

Newtons law of cooling states that the temperature of an object changes at a rate proportional to the difference between the temperature of the object itself and the temperature of its surroundings (the ambient air temperature in most cases). Suppose that the ambient temperature is 70F and that the rate constant is 0.05 (min)1. Write a differential equation for the temperature of the object at any time. Note that the differential equation is the same whether the temperature of the object is above or below the ambient temperature.

A certain drug is being administered intravenously to a hospital patient. Fluid containing 5 mg/cm3 of the drug enters the patients bloodstream at a rate of 100 cm3/h. The drug is absorbed by body tissues or otherwise leaves the bloodstream at a rate proportional to the amount present, with a rate constant of 0.4 (h)1. (a) Assuming that the drug is always uniformly distributed throughout the bloodstream, write a differential equation for the amount of the drug that is present in the bloodstream at any time. (b) How much of the drug is present in the bloodstream after a long time?

For small, slowly falling objects, the assumption made in the text that the drag force is proportional to the velocity is a good one. For larger, more rapidly falling objects, it is more accurate to assume that the drag force is proportional to the square of the velocity.2 (a) Write a differential equation for the velocity of a falling object of mass m if the drag force is proportional to the square of the velocity. (b) Determine the limiting velocity after a long time.(c) If m = 10 kg, find the drag coefficient so that the limiting velocity is 49 m/s. (d) Using the data in part (c), draw a direction field and compare it with Figure 1.1.3.

In each of Problems 26 through 33 draw a direction field for the given differential equation. Based on the direction field, determine the behavior of y as t . If this behavior depends on the initial value of y at t = 0, describe this dependency. Note that the right sides of these equations depend on t as well as y; therefore their solutions can exhibit more complicated behavior than those in the text.y = 2 + t y

In each of Problems 26 through 33 draw a direction field for the given differential equation. Based on the direction field, determine the behavior of y as t . If this behavior depends on the initial value of y at t = 0, describe this dependency. Note that the right sides of these equations depend on t as well as y; therefore their solutions can exhibit more complicated behavior than those in the text.

In each of Problems 26 through 33 draw a direction field for the given differential equation. Based on the direction field, determine the behavior of y as t . If this behavior depends on the initial value of y at t = 0, describe this dependency. Note that the right sides of these equations depend on t as well as y; therefore their solutions can exhibit more complicated behavior than those in the text.

In each of Problems 26 through 33 draw a direction field for the given differential equation. Based on the direction field, determine the behavior of y as t . If this behavior depends on the initial value of y at t = 0, describe this dependency. Note that the right sides of these equations depend on t as well as y; therefore their solutions can exhibit more complicated behavior than those in the text.y = t + 2y

In each of Problems 26 through 33 draw a direction field for the given differential equation. Based on the direction field, determine the behavior of y as t . If this behavior depends on the initial value of y at t = 0, describe this dependency. Note that the right sides of these equations depend on t as well as y; therefore their solutions can exhibit more complicated behavior than those in the text.y = 3 sin t + 1 + y

In each of Problems 26 through 33 draw a direction field for the given differential equation. Based on the direction field, determine the behavior of y as t . If this behavior depends on the initial value of y at t = 0, describe this dependency. Note that the right sides of these equations depend on t as well as y; therefore their solutions can exhibit more complicated behavior than those in the text.y = 2t 1 y2

In each of Problems 26 through 33 draw a direction field for the given differential equation. Based on the direction field, determine the behavior of y as t . If this behavior depends on the initial value of y at t = 0, describe this dependency. Note that the right sides of these equations depend on t as well as y; therefore their solutions can exhibit more complicated behavior than those in the text.

In each of Problems 26 through 33 draw a direction field for the given differential equation. Based on the direction field, determine the behavior of y as t . If this behavior depends on the initial value of y at t = 0, describe this dependency. Note that the right sides of these equations depend on t as well as y; therefore their solutions can exhibit more complicated behavior than those in the text.y = 1 6 y3 y 1 3 t