Consider the differential equation
y′ = 3y − 9.
(a) (1 pt) Make a direction field plot for this function which includes the point
(t, y) = (0, 2).
(b) (2 pts) Solve the equation by dividing 3y − 9 and using the method outlined in
Section 1.2.
(c) (1 pt) Find the solution which corresponds to y(0) = 2.
(d) (1 pt) Plot the solution corresponding to y(0) = 2 on your direction field plot.
Consider the differential equation y′ = 3y − 9. (a) (1 pt) Make a direction field...
(1) Solve the differential equation y 2xy, y(1)= 1 analytically. Plot the solution curve for the interval x 1 to 2 (see both MS word and Excel templates). 3 pts (2) On the same graph, plot the solution curve for the differential equation using Euler's method. 5pts (3) On the same graph, plot the solution curve for the differential equation using improved Euler's method. 5pts (4) On the same graph, plot the solution curve for the differential equation using Runge-Kutta...
Consider the differential equation y"+ 3y' + by = 0 where b is a real number. a) Find the value of b that makes the above differential equation critically damped. b) Solve the above differential equation for the value b=4 where y(0) = 1 and y'(0) = 1. Put the solution into the form Asin(ot+o).
solve please 8 Sketch the direction field of the differential equation dx dt Verify that x t-1 Ce is the solution of the equation. Sketch the solution curve for which x(0) 2, and that for which x(4) 0, and check that these are consistent with your direction field. MAPI R has tools for exam 8 Sketch the direction field of the differential equation dx dt Verify that x t-1 Ce is the solution of the equation. Sketch the solution curve...
1. Consider the differential equation: 49) – 48 – 24+246) – 15x4+36” – 36" = 1-3a2+e+e^+2sin(2x)+cos - *cos(a). (a) Suppose that we know the characteristic polynomial of its corresponding homogeneous differential equation is P(x) = x²(12 - 3)(1? + 4) (1 - 1). Find the general solution yn of its corresponding homogeneous differential equation. (b) Give the form (don't solve it) of p, the particular solution of the nonhomogeneous differential equation 2. Find the general solution of the equation. (a)...
Chapter 1, Section 1.1, Question 15 Identify the differential equation that corresponds to the given direction field. y 3 \llll IllII O y' = y(y + 3) Ó y = y(y - 3) y' = y-3 y = 3-y y = 3y - 1 y=3+y Click if you would like to Chau Work for this an
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Given the differential equation y" – 4y' + 3y = - 2 sin(2t), y(0) = -1, y'(0) = 2 Apply the Laplace Transform and solve for Y(8) = L{y} Y(S) -
1. (25 pts) An autonomous differential equation has an unstable equilibrium solution at y = -1, a semi-stable equilibrium solution at y = 0, and a stable equilibrium at y = 5/2. a. Sketch the slope field for the system. b. Propose a first order differential equation (use x as the independent variable) that meets the description above. c. What solution method(s) can be used to solve this system?
consider the autonomous equation 2. Consider the autonomous equation y=-(y2-6y-8) (a) Use the isocline method to sketch a direction field for the equation (b) Sketch the solution curves corresponding to the following intitial conditions: (1) y(0) 1 (2) y(0) =3 (3) y(0)=5 (4) 3y(0) 2 (5) y(0) = 4 (c) What are equilibrium solutions, and classify its equilibrium them as: sink (stable), source, node. (d) What is limy(t) if y(0) = 6? too 2. Consider the autonomous equation y=-(y2-6y-8) (a)...