x(t+2) = x(t+1) . x(t) , t >=0 Solve a transformed version of the difference equation....

Consider the differential equation x′=[2 −2 4 −2], with x(0)=[1 1] Solve the differential equation wherex=[x(t)y(t)]...

Consider the differential equation x′=[2 −2 4 −2], with x(0)=[1 1] Solve the differential equation wherex=[x(t)y(t)] please write as neat as possible better if typed and explain clearly with step by step work

Solve the below boundary value equation 1. Ut=2uxx o<x<pi 0<t 2. u(0,t) = ux(pi,t) 0<t 3....

Solve the below boundary value equation 1. Ut=2uxx o<x<pi 0<t 2. u(0,t) = ux(pi,t) 0<t 3. u(x,0) = 1-2x 0<x<pi

Solve the heat equation ut = k uxx, 0 < x < L, t > 0...

Solve the heat equation ut = k uxx, 0 < x < L, t > 0 u(0, t) = u(L, t) = 0, t > 0 u(x, 0) = f(x), 0 < x < L a) f(x) = 6 sin 9πx L b) f(x) = 1 if 0 < x ≤ L/2 2 if L/2 < x < L

x’+2x=sin(t), x(0)=1 solve the first order differential equation.

x’+2x=sin(t), x(0)=1 solve the first order differential equation.

PLEASE solve with all the steps and correctly. Solve the given system: x'-4x+3y''=t^2 and x'+x+y'=0

PLEASE solve with all the steps and correctly. Solve the given system: x'-4x+3y''=t^2 and x'+x+y'=0

1) x(t+2) = x(t+1) + x(t) , t >=0 determine a closed solution (i.e. a solution...

1) x(t+2) = x(t+1) + x(t) , t >=0 determine a closed solution (i.e. a solution dependent only on time t ) for above eqn. Verify your answer by evaluating your solution at t = 0 , 1, 2, 3, 4, 5. We are given x(0) = 1 and x(1) = 1

-12.67x-9.67y-8.67z=0......(1) -11.67x-21.67y-5.67z=0.....(2) -19.67x-18.67-13.87z=0.....(3) By using this equations, apply on this equation “x^2+y^2+z^2=1” Solve for x,y, z....

-12.67x-9.67y-8.67z=0......(1) -11.67x-21.67y-5.67z=0.....(2) -19.67x-18.67-13.87z=0.....(3) By using this equations, apply on this equation “x^2+y^2+z^2=1” Solve for x,y, z. -12.67x-9.67y-8.67z=0.....(1) -11.67x-21.67y-5.67z=0....(2) -19.67x-18.67y-13.87z=0....(3) By using this equations, apply on it “x^2+y^2+z^2=1” Solve for x,y, z.

Solve the heat equation and find the steady state solution : uxx=ut 0<x<1, t>0, u(0,t)=T1, u(1,t)=T2,...

Solve the heat equation and find the steady state solution : uxx=ut 0<x<1, t>0, u(0,t)=T1, u(1,t)=T2, where T1 and T2 are distinct constants, and u(x,0)=0

Given the equation, a(second partial-∂ x/∂ t)  + b(∂ x /∂ t-first partial)+ c x = 0...

Given the equation, a(second partial-∂ x/∂ t)  + b(∂ x /∂ t-first partial)+ c x = 0 show that A ⅇⅈ ω t is a solution for certain values of ω (Be sure to specify all relevant values of ω). (Begin by substituting x = A ⅇⅈ ω t into the above equation and then solve for values of ω such that the equation is satisfied for all values of A and t

Solve the wave equation: utt = c2uxx, 0<x<pi, t>0 u(0,t)=0, u(pi,t)=0, t>0 u(x,0) = sinx, ut(x,0)...

Solve the wave equation: utt = c2uxx, 0<x<pi, t>0 u(0,t)=0, u(pi,t)=0, t>0 u(x,0) = sinx, ut(x,0) = sin2x, 0<x<pi