(15 points) Solve the initial value problem y' = (x + y - 1)? with y(0)...
(1 point) Solve the initial value problem 2yy' 3 = y 3x with y(0) = 9 a. To solve this, we should use the substitution y^2 help (formulas) With this substitution, help (formulas) y' = help (formulas) Enter derivatives using prime notation (e.g., you would enter y' for b. After the substitution from the previous part, we obtain the following linear differential equation in x, u, u'. help (equations) c. The solution to the original initial value problem is described...
Solve the initial value problem \(y y^{\prime}+x=\sqrt{x^{2}+y^{2}}\) with \(y(3)=\sqrt{40}\)a. To solve this, we should use the substitution\(\boldsymbol{u}=\)\(u^{\prime}=\)Enter derivatives using prime notation (e.g., you would enter \(y^{\prime}\) for \(\frac{d y}{d x}\) ).b. After the substitution from the previous part, we obtain the following linear differential equation in \(\boldsymbol{x}, \boldsymbol{u}, \boldsymbol{u}^{\prime}\)c. The solution to the original initial value problem is described by the following equation in \(\boldsymbol{x}, \boldsymbol{y}\)Previous Problem List Next (1 point) Solve the initial value problem yy' + -y2 with...
(1 point) Solve the initial value problem 2yy' + 4 = y2 + 4.r with y(O) = 5. a. To solve this, we should use the substitution help (formulas) With this substitution, y = help (formulas) y' = help (formulas) Enter derivatives using prime notation (e.g., you would enter y' for ). b. After the substitution from the previous part, we obtain the following linear differential equation in 2, u, u'. help (equations) C. The solution to the original initial...
[ 15 ports) Save the initial value problem y' - (x + y - 1)' with y(0) - 0 a to solve this, we should use the substitution help (formulas) help (formulas) Enter derivatives using prime notation (e 9. you would enter y' for d. After the substitution from the previous part, we obtain the following linear differential equation in z, u, u' help (equations) c The solution to the orginal initial value problem is described by the following equation...
part c Solve the initial value problem yy' + + y with y(4) - 33 a. To solve this, we should use the substitution u=x^2+y^2 help (formulas '= 2x+2yi help (formulas) Enter derivatives using prime notation (e.g.. you would enter y' for ). N b . After the substitution from the previous part, we obtain the following linear differential equation in ruu 1/2 sqrt() help. (equations e. The solution to the original initial value problem is described by the following...
Solve the initial value problem 2yy'+3=y2+3x with y(0)=4a. To solve this, we should use the substitution u=With this substitution,y=y'=uEnter derivatives using prime notation (e.g., you would enter y' for dy/dx ).b. After the substitution from the previous part, we obtain the following linear differential equation in x, u, u'c. The solution to the original initial value problem is described by the following equation in x, y.
Solve the initial value problem 2yy' + 2 = y2 + 2x with y(0) = 4. To solve this, we should use the substitution u = With this substitution, y = y' = Enter derivatives using prime notation (e.g., you would enter y' for dy/dx). After the substitution from the previous part, we obtain the following linear differential equation in x, u, u'. The solution to the original initial value problem is described by the following equation in x, y.
a) To solve this, we should use the substitution Enter derivatives using prime notation (e.g., you would enter for ).b) After the substitution from the previous part, we obtain the following linear differential equation in .c) The solution to the original initial value problem is described by the following equation in .
(1 point) Solve the Bernoulli initial value problem - 2 'y', y(1)=2 For this example we haven We obtain the equation + given by Solving the resulting first order linear equation for u we obtain the general solution with arbitrary constant Then transforming back into the variables 2 and y and using the initial condition to find C Finally we obtain the explicit solution of the initial value problem as
Problem 5. (1 point) A Bernoulli differential equation is one of the form +P()y= Q()y" (*) Observe that, if n = 0 or 1, the Bernoulli equation is linear. For other values of n, the substitution u =y- transforms the Bemoulli equation into the linear equation + (1 - x)P(3)u = (1 - x)^(x). Consider the initial value problem ry' +y = -3.xy?, y(1) = 2. (a) This differential equation can be written in the form (*) with P(1) =...