Solution approximation using Euler's Method and Slope Field representations
Given a first-order ordinary differential equation (ODE) of the form:
Euler's method is a simple numerical technique for solving ordinary differential equations (ODEs) numerically and serves as the foundation for more sophisticated numerical methods.
It approximates the solution to the ODE by performing successive linear approximations based on the derivative of the function
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Initial Condition: Start with the initial condition
$y(x_0) = y_0$ . -
Step Size: Choose a small step size
$h$ that determines the distance between consecutive points along the$x$ -axis. -
Iteration: For each step
$i$ :- Calculate the slope
$f(x_i, y_i)$ at the current point$(x_i, y_i)$ . - Use the slope to approximate the change in
$y$ over the interval$[x_i, x_{i+1}]$ :$$\Delta y = f(x_i, y_i) \cdot h$$ - Update the values of
$x$ and$y$ for the next iteration:$$x_{i+1} = x_i + h$$ $$y_{i+1} = y_i + \Delta y$$
- Calculate the slope
- Repeat: Repeat the process until the desired endpoint is reached.
Euler's method is a first-order method, meaning its error decreases linearly with the step size
Approximate the solution of the initial value problem
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fname: Function handle for$f(t,y(t))$ . -
y0: The initial value$(y(t_0)=y_0)$ . -
t0: The lower limit of integration. -
T: The upper limit of integration. -
N: The number of subintervals in which$[t_0,T]$ is divided.
t: Mesh points.y: Approximate values of the solution at the mesh points.