6. For the non-linear differential equation: ??2 2 ??=? −(?+1) +1 (a) Use a computer algebra...

Solve the following differential equations y''-4y'+4y=(x+1)e2x (Use Wronskian) y''+(y')2+1=0 (non linear second order equation)

Solve the following differential equations y''-4y'+4y=(x+1)e2x (Use Wronskian) y''+(y')2+1=0 (non linear second order equation)

In this problem we consider an equation in differential form ???+???=0 The equation (6?^(1/?)+4?^3?^−3)??+(6?^2?^−2+4)??=0 in differential...

In this problem we consider an equation in differential form ???+???=0 The equation (6?^(1/?)+4?^3?^−3)??+(6?^2?^−2+4)??=0 in differential form ?˜??+?˜??=0 is not exact. Indeed, we have ?˜?−?˜?/M=______ is a function of ? alone. Namely we have μ(y)= Multiplying the original equation by the integrating factor we obtain a new equation ???+???=0 ?=____ ?=_____ Which is exact since ??=______ ??=_______ are equal. This problem is exact. Therefore an implicit general solution can be written in the form  ?(?,?)=?F where ?(?,?)=__________

(Linear Algebra) Consider the difference equation. yk+2 - 4yk+1 + 4yk = 0, for all k...

(Linear Algebra) Consider the difference equation. yk+2 - 4yk+1 + 4yk = 0, for all k (a) After using auxiliary equation, the solutions have the form rk and k(rk). Find the root, r, and show that yk = k(rk) is a solution. (b) Show that rk and k(rk) are linearly independent and form the general solution of the difference equation.

Use the Integrating Factor Technique to find the solution to the first-order linear differential equation (1...

Use the Integrating Factor Technique to find the solution to the first-order linear differential equation (1 − ? ∙ ?in(?)) ∙ ?? − cos(?) ∙ ?? = 0 with ?(?) = 1

1. If x1(t) and x2(t) are solutions to the differential equation x" + bx' + cx...

1. If x1(t) and x2(t) are solutions to the differential equation x" + bx' + cx = 0 is x = x1 + x2 + c for a constant c always a solution? Is the function y= t(x1) a solution? Show the works 2. Write sown a homogeneous second-order linear differential equation where the system displays a decaying oscillation.

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...

1. By hand, sketch the slope field for the DE x ′ = x(1 − x/4)...

1. By hand, sketch the slope field for the DE x ′ = x(1 − x/4) in the window 0 ≤ t ≤ 8, 0 ≤ x ≤ 8 at the integer lattice points. What is the value of the slope field along the lines x = 0 and x = 4? Show that x(t) = 0 and x(t) = 4 are constant solutions to the DE. 2. Draw several isoclines of the differential equation x ′ = x 2...

Consider the following exact differential equation ? sin 2??? − (1 + ? 2 + cos2...

Consider the following exact differential equation ? sin 2??? − (1 + ? 2 + cos2 ?)?? = 0. Show that the potential function ?(?, ?) corresponding to this differential equation is ?(?, ?) = −????2? − ? − ? 3 3 .

B. a non-homogeneous differential equation, a complementary solution, and a particular solution are given. Find a...

B. a non-homogeneous differential equation, a complementary solution, and a particular solution are given. Find a solution satisfying the given initial conditions. y''-2y'-3y=6 y(0)=3 y'(0) = 11 yc= C1e-x+C2e3x yp = -2 C. a third-order homogeneous linear equation and three linearly independent solutions are given. Find a particular solution satisfying the given initial conditions y'''+2y''-y'-2y=0, y(0) =1, y'(0) = 2, y''(0) = 0 y1=ex, y2=e-x,, y3= e-2x

1) State the main difference between an ODE and a PDE? 2) Name two of the...

1) State the main difference between an ODE and a PDE? 2) Name two of the three archetypal PDEs? 3) Write the equation used to compute the Wronskian for two differentiable functions, y1 and y2. 4) What can you conclude about two differentiable functions, y1 and y2, if their Wronskian is nonzero? 5) (2 pts) If two functions, y1 and y2, solve a 2nd order DE, what does the Principle of Superposition guarantee? 6) (8 pts, 4 pts each) State...