slope fields euler’s method and integrating factors 6. Draw the direction field of the given differential...
Draw a direction field for the given differential equation. Based on the direction field, determine the behavior of y at t -> oo. If this behavior depends on the initial value of y at t 0, describe this dependency. (b) y'-2t-1-y.
Number 8 In each of Problems 7 through 10, draw a direction field for the given differential equation. Based on the direction field, determine the behavior of y ast oo. 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 1 through 4 draw a direction field for the given differential equations. 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. 1. y ' = 3 + 2y 2. y ' = 3 − 2y 3. y ' = −y(5 − y) 4. y ' = y(y − 2)2
2. Differential equations and direction fields (a) Find the general solution to the differential equation y' = 20e3+ + + (b) Find the particular solution to the initial value problem y' = 64 – 102, y(0) = 11. (e) List the equilibrium solutions of the differential equation V = (y2 - 1) arctan() (d) List all equilibrium solutions of the differential equation, and classify the stability of each: V = y(y - 6)(n-10) (e) Use equilibrium solutions and stability analysis...
(a) Draw a direction field for the given differential equation. (b) Based on an inspection of the direction field, describe how solutions behave for large t. All solutions seem to approach a line in the region where the negative and positive slopes meet each other. The solutions appear to be oscillatory. All solutions seem to eventually have positive slopes, and hence increase without bound. If y(0) > 0, solutions appear to eventually have positive slopes, and hence increase without bound....
Draw a direction field for the given differential equation and state whether you think that the solutions for t >0 are converging or diverging. yy(3 ty) - Converge. Diverge Converge for y 20,diverge for y< 0 Converge for y<U, diverge for y 2 0 Draw a direction field for the given differential equation and state whether you think that the solutions for t >0 are converging or diverging. yy(3 ty) - Converge. Diverge Converge for y 20,diverge for y
1. Consider the differential equation y' = y-t. (a) Construct a slope field for this equation. (b) Find the general solution to this differential equation. (c) There is exactly one solution that is given by a straight line. Write the equation for this line and draw it on the slope field.
differential equations 6. (15 pts) Consider the following differential equation (10 pta) Slotch the direction fields for this problem (considert und h.(5 pts) For the initial condition (0) - 3/2 what is the behavior of S
Lab 6 Direction Fields Math 1B II. Some of the qualitative information that you derived above can be found without plotting a direction field. Some information can be observed in the differential equation y'=f(x,y). 5) Consider the differential equation y' = f(x,y), where f(x,y) is continuous and f(x, 3) = -1 for all x. If y(0) <3, can y(x) → as x increases? Explain your answer. (Hint: it may help to sketch what little you can of the direction field.)...
I need help with question #3 When there is no fishing, the growth of a population of clown fish is governed by the following differential equation: dy dt 200 where y is the number of fish at time t in years. 1. Solve for the equilibrium value(s) and determine their stability. Create a slope field for this differential equation. Use the slope field to sketch solutions for various initial values. 2. 3. Summarize the behavior of the solutions and how...