Solve t2 x' + x2 = tx for t > 0.

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

Solve the initial-value problem. y"-6y'+9y=0; y(0)=2, y'(0)=3 Given that y1=x2 is a solution to y"+(1/x) y'-(4/x2)...

Solve the initial-value problem. y"-6y'+9y=0; y(0)=2, y'(0)=3 Given that y1=x2 is a solution to y"+(1/x) y'-(4/x2) y=0, find a second, linearly independent solution y2. Find the Laplace transform. L{t2 * tet} Thanks for solving!

In the right-half tx plane (t ≥ 0), plot the nullclines of the differential equation x′...

In the right-half tx plane (t ≥ 0), plot the nullclines of the differential equation x′ = 2x2(x − 4√t). Determine the sign of the slope field in the regions separated by the nullclines. Sketch the approximate solution curve passing through the point (1,4). Why can’t your curve cross the x = 0 axis?

Solve the linear system x' - 4x + y" = t2 x' + x + y'...

Solve the linear system x' - 4x + y" = t2 x' + x + y' = 0

Solve the heat equation and find the steady state solution: uxx = ut, 0 < x...

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

solve the wave problem ytt(x,t) = 100yxx(x,t) 0<x<1 0<t y(0,t) = y(1,t) = 0 0<t y(x,0)...

solve the wave problem ytt(x,t) = 100yxx(x,t) 0<x<1 0<t y(0,t) = y(1,t) = 0 0<t y(x,0) = x 0<x<1 yt(x,0) = 5 0<x<1

Solve: uxx + uyy = 0 in {(x,y) st x2 + y2 < 1 , x...

Solve: uxx + uyy = 0 in {(x,y) st x2 + y2 < 1 , x > 0, y > 0} u = 0 on x=0 and y=0 ∂u/∂r = 1 on r=1

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

Solve the following initial/boundary value problem: ∂u(t,x)/∂t = ∂^2u(t,x)/∂x^2 for t>0, 0<x<π, u(t,0)=u(t,π)=0 for t>0, u(0,x)=sin^2x...

Solve the following initial/boundary value problem: ∂u(t,x)/∂t = ∂^2u(t,x)/∂x^2 for t>0, 0<x<π, u(t,0)=u(t,π)=0 for t>0, u(0,x)=sin^2x for 0≤x≤ π. if you like, you can use/cite the solution of Fourier sine series of sin^2(x) on [0,pi] = 1/4-(1/4)cos(2x) please show all steps and work clearly so I can follow your logic and learn to solve similar ones myself.

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

x(t+2) = x(t+1) . x(t) , t >=0 Solve a transformed version of the difference equation. Think of a transformation that takes multiplication to addition, apply this transformation to above ewn, and solve the transformed system. We are given x(0) = 1 and x(1) = 1