Classify each ode as linear or non linear, autonomous or not. If an ode is linear...
What is the general intuition behind picking a PARTICULAR solution to a second-order, linear, non-homogenous, ODE y′′+p(t)y′+q(t)y=g(t) instead of following the rules for example when seeing an exponential you know the guess has to include an exponential? P.S I heard the intuition follow somehow checking your guess with the ODE on the left side of the equation and its derivatives before actually applying it, but how?
Question 5 The ODE Y' +17xy= 2 xy2 is a exact ODE a. b. second order linear non homogeneous ODE Bernoulli equation c. d. linear non-homogeneous ODE
Le-t are solutions of a second-order /2e5t and y2(t) Suppose y1(t) = homogeneous linear ODE on R. Which one of the following is also a solution to the same ODE? y(t) e5t-2 y(t) ee y(t) e5t e 1 y(t) 2e5t Le-t are solutions of a second-order /2e5t and y2(t) Suppose y1(t) = homogeneous linear ODE on R. Which one of the following is also a solution to the same ODE? y(t) e5t-2 y(t) ee y(t) e5t e 1 y(t) 2e5t
3. a) Classify each ODE by order and linearity: y" – 3xy' + xy = 0 b) y(4) + 2xy" - x?y' - xy' + sin y = 0 c) 2.5** 12.5x = sint
just focus on A,B,D 1. Homogeneous ODE Find a general solution of the linear non-constant coefficient, homogeneous ODE for y(x) x3y'" – 3xy" + (6 – x2)xy' – (6 – x?)y = 0 as follows. a) You are given that yı(x) = x is a solution to the above homogeneous ODE. Confirm (by substitution) that this is the case. b) Apply reduction of order to find the remaining two solutions, then state the general solution. (Hint: The substitution y2(x) =...
Please answer (i) (ii) and (iii) 5. For each of the following linear homogeneous ODE, do the fol- lowing. (a) Identify p(x) and (2) and, from them, determine the least possible guaranteed interval of convergence about the specified center Jo. (b) Write the general solution in the form of a power series, obtaining the first three non-vanishing powers of (x - Xo) in each of yı (2) and y2(2). 2- +y=0, = 1 y" + cos(x)y=0, x = 0 15"...
You are told that a certain second order, linear, constant coefficient, homogeneous ode has the solutions y1(x) = e^γx cos ωx, and y2(x) = e^γx sin ωx, where γ and ω are real-valued parameters and −∞ < x < ∞. 4. You are told that a certain second order, linear, constant coefficient, homogeneous ODE has the solutions where γ and w are real-valued parameters and-oo < x < oo. (a) Compute the Wronskian for this set of solutions. (b) Using...
2. (8 points) Solve the linear, 1st order ODE with initial value: dy dr 3. (7 points) Find all critical points and the phase portrait of the autonomous Ist order ODE dy dr -5y+4 Classify each critical point as asymptotically stable, unstable or semi-stable. Sketch typical solution curves in the regions in the ry plane separated by equilibrium solutions. dy dx (S points) Solve the Bernoulli equation:-(- 31-1 7. (8 points) Solve the ODE by variation of parameters: -4y+4y (+...
3. A ODE is called autonomous if it contains no independent variables. That is y f (x, y) is actually just g(y). Draw a ODE slope field for the following autonomous f2y722y 3 + Sketch a solution that goes through y(0) = -1 and also sketch the solution that goes through y(0) 0. 3. A ODE is called autonomous if it contains no independent variables. That is y f (x, y) is actually just g(y). Draw a ODE slope field...
3. For each ODE with non-constant coefficients, use the given homogeneous solution to find a particular solution by variation of parameters. (c) y" – 21-2y=1 Yh = 60-1 + car? — (k) z’y" – xy' + y = r, yh = Cr + C22 ln(2).