@Retsam
Consider the initial value problem
y'=f(t,y(t)), a<=t<=b
y(a)=y_0
The formula for the backward Euler method is given by the formula:
y^(n+1)=y^n+h[rho*f(t^n, y^n)+(1-rho)f(t^(n+1),y^(n+1))]
for a uniform partition of [a,b] with step h=(b-a)/N with rho=0.
At each step we will have to solve a nonlinear equation for the computation of y^(n+1). This can be done with the use of Newton's method, which is defined as follows:
Let g(x) be a function and x* a root of it, which we want to approach. Given an initial approximation of the root, x_0, we define the iterative procedure x_(k+1)…