dy/dx = x^4/y^2 initial condition y(1)= 1 a) use eulers method to approximate the solution at...

dy/dx = x^4/y^2 a) use eulers method to approximate the solution at x =1.6 starting at...

dy/dx = x^4/y^2 a) use eulers method to approximate the solution at x =1.6 starting at the initial condition of y(1)=1 and a step size of delta x=0.2 b) solve this differential equation exactly using separation if variables and the inital condition y(1)=1 c) what is the exact vwlue of y(1.6) for the solution found in part b

Consider the initial value problem dy/dx= 6xy2 y(0)=1 a) Solve the initial value problem explicitly b)...

Consider the initial value problem dy/dx= 6xy2 y(0)=1 a) Solve the initial value problem explicitly b) Use eulers method with change in x = 0.25 to estimate y(1) for the initial value problem c) Use your exact solution in (a) and your approximate answer in (b) to compute the error in your approximation of y(1)

Solve the Homogeneous differential equation (7 y^2 + 1 xy)dx - 1 x^2 dy = 0...

Solve the Homogeneous differential equation (7 y^2 + 1 xy)dx - 1 x^2 dy = 0 (a) A one-parameter family of solution of the equation is y(x) = (b) The particular solution of the equation subject to the initial condition y(1) =1/7.

Use the method for solving homogeneous equations to solve the following differential equation. (9x^2-y^2)dx+(xy-x^3y^-1)dy=0 solution is...

Use the method for solving homogeneous equations to solve the following differential equation. (9x^2-y^2)dx+(xy-x^3y^-1)dy=0 solution is F(x,y)=C, Where C= ?

solve the IVP for dy/dx+(1/x)*y=17y^4, initial condition y (1) = 1 y(x)= please break it down...

solve the IVP for dy/dx+(1/x)*y=17y^4, initial condition y (1) = 1 y(x)= please break it down like your explain it to a fifth grade of

dy/dx = ysin(4x)/(y-4) a) Find region of xy plane where the d.e has a unique solution...

dy/dx = ysin(4x)/(y-4) a) Find region of xy plane where the d.e has a unique solution b) Solve the d.e by seperation of variables. Is there a lost solution? c) Find the solution of the ivp where the initial condition is y(-pi) = -1

Using Euler's method Calculate the exact solution and investigate the accuracy of your approximations. dy/dx=x-xy y(1)=0...

Using Euler's method Calculate the exact solution and investigate the accuracy of your approximations. dy/dx=x-xy y(1)=0 dx=0.2

Consider the following differential equation: dy/dx = −(3xy+y^2)/x^2+xy (a) Rewrite this equation into the form M(x,...

Consider the following differential equation: dy/dx = −(3xy+y^2)/x^2+xy (a) Rewrite this equation into the form M(x, y)dx + N(x, y)dy = 0. Determine if this equation is exact; (b) Multiply x on both sides of the equation, is the new equation exact? (c) Solve the equation based on Part (a) and Part (b).

Use dy/dx + p(x)y = f(x) has the solution y = y_c + y_p to solve....

Use dy/dx + p(x)y = f(x) has the solution y = y_c + y_p to solve. (Integrating Factor method) Find the General solution for the DEQ: dy/dx + 2xy = y + 4x - 2. Show step by step. Please explain or I will give a down-vote. Thank you

A Bernoulli differential equation is one of the form dy/dx+P(x)y=Q(x)y^n (∗) Observe that, if n=0 or...

A Bernoulli differential equation is one of the form dy/dx+P(x)y=Q(x)y^n (∗) Observe that, if n=0 or 1, the Bernoulli equation is linear. For other values of n, the substitution u=y^(1−n) transforms the Bernoulli equation into the linear equation du/dx+(1−n)P(x)u=(1−n)Q(x). Consider the initial value problem xy′+y=−8xy^2, y(1)=−1. (a) This differential equation can be written in the form (∗) with P(x)=_____, Q(x)=_____, and n=_____. (b) The substitution u=_____ will transform it into the linear equation du/dx+______u=_____. (c) Using the substitution in part...