y'=2+t^2+y^2 0<t<1 y(0)=0 evaluate the step size for the Euler method to have an error less...

Given : dy/dt = -100000y + 99999 e^(-t) a. If y(0)=0 use the explicit Euler method...

Given : dy/dt = -100000y + 99999 e^(-t) a. If y(0)=0 use the explicit Euler method to obtain a solution using a step size of 0.1. Carry out 2 iterations. What do you notice? b. Estimate the minimum step size required to maintain stability using the explicit Euler method. b. Repeat the problem using the implicit Euler method to obtain a solution from t=0 to 2 using a step size of 0.1.

1313) Given the DEQ y'=5x-y^2*6/10. y(0)=8/2. Determine y(2) by Euler integration with a step size (delta_x)...

1313) Given the DEQ y'=5x-y^2*6/10. y(0)=8/2. Determine y(2) by Euler integration with a step size (delta_x) of 0.2. ans:1 Please help solve this. Thnaks

Solve the initial value problem below for the Cauchy-Euler equation t^2y"(t)+10ty'(t)+20y(t)=0, y(1)=0, y'(1)=2 y(t)=

Solve the initial value problem below for the Cauchy-Euler equation t^2y"(t)+10ty'(t)+20y(t)=0, y(1)=0, y'(1)=2 y(t)=

Given the initial value problem: y'=6√(t+y),  y(0)=1 Use Euler's method with step size h = 0.1 to...

Given the initial value problem: y'=6√(t+y),  y(0)=1 Use Euler's method with step size h = 0.1 to estimate: y(0.1) = y(0.2) =

Solve the Euler Equation t^2(y'')-5ty'+9y=0, t>0

Solve the Euler Equation t^2(y'')-5ty'+9y=0, t>0

6. Consider the initial value problem y' = ty^2 + y, y(0) = 0.25, with (exact)...

6. Consider the initial value problem y' = ty^2 + y, y(0) = 0.25, with (exact) solution y(t). (a) Verify that the solution of the initial value problem is y(t) = 1/(3e^(-t) − t + 1) and evaluate y(1) to at least four decimal places. (b) Use Euler’s method to approximate y(1), using a step size of h = 0.5, and evaluate the difference between y(1) and the Euler’s method approximation. (c) Use MATLAB to implement Euler’s method with each...

4. For the initial-value problem y′(t) = 3 + t − y(t), y(0) = 1: (i)...

4. For the initial-value problem y′(t) = 3 + t − y(t), y(0) = 1: (i) Find approximate values of the solution at t = 0.1, 0.2, 0.3, and 0.4 using the Euler method with h = 0.1. (ii) Repeat part (i) with h = 0.05. Compare the results with those found in (i). (iii) Find the exact solution y = y(t) and evaluate y(t) at t = 0.1, 0.2, 0.3, and 0.4. Compare these values with the results of...

use euler method y'=32-1/5yx-1/5y,y(0)=1, from 1 to 10 . show graph

use euler method y'=32-1/5yx-1/5y,y(0)=1, from 1 to 10 . show graph

Solve the IVP with Cauchy-Euler ODE: x^2 y''+3xy'+4y=0; y(1)=0, y’(1)=−2

Solve the IVP with Cauchy-Euler ODE: x^2 y''+3xy'+4y=0; y(1)=0, y’(1)=−2

x^2y'' − 3xy'+ 4y = 0 ; y(1)=5 y'(1)=3 differential equation using the Cauchy-Euler method

x^2y'' − 3xy'+ 4y = 0 ; y(1)=5 y'(1)=3 differential equation using the Cauchy-Euler method