Find perticular solution y''-y'=e^x y1 = e^x found y2 = -1

show that y1= e^x and y2=1+x form a basis for the general solution of xy''-(1+x)y'+y=0 by...

show that y1= e^x and y2=1+x form a basis for the general solution of xy''-(1+x)y'+y=0 by verifying that they both work, and are linearly independent using the wronskian.

f(y1,y2)=k(1−y2), 0≤y1≤y2≤1.joint probability density function: a) Find P(Y1≤0.35|Y2=0.3) b) Find E[Y1|Y2=y2]. c) Find E[Y1|Y2=0.3]

f(y1,y2)=k(1−y2), 0≤y1≤y2≤1.joint probability density function: a) Find P(Y1≤0.35|Y2=0.3) b) Find E[Y1|Y2=y2]. c) Find E[Y1|Y2=0.3]

1) find a solution for a given differential equation y1'=3y1-4y2+20cost ->y1 is not y*1 & y2...

1) find a solution for a given differential equation y1'=3y1-4y2+20cost ->y1 is not y*1 & y2 is not y*2 y2'=y1-2y2 y1(0)=0,y2(0)=8 2)by setting y1=(theta) and y2=y1', convert the following 2nd order differential equation into a first order system of differential equations(y'=Ay+g) (theta)''+4(theta)'+10(theta)=0

Find the function y1(t) which is the solution of 4y″+32y′+64y=0 with initial conditions y1(0)=1,y′1(0)=0. y1(t)=? Find...

Find the function y1(t) which is the solution of 4y″+32y′+64y=0 with initial conditions y1(0)=1,y′1(0)=0. y1(t)=? Find the function y2(t) which is the solution of 4y″+32y′+64y=0 with initial conditions y2(0)=0, y′2(0)=1. y2(t)= ? Find the Wronskian of these two solutions you have found: W(t)=W(y1,y2). W(t)=?

The indicated function y1(x) is a solution of the given differential equation. Use reduction of order...

The indicated function y1(x) is a solution of the given differential equation. Use reduction of order or formula (5) in Section 4.2, y2 = y1(x) e−∫P(x) dx y 2 1 (x) dx     (5) as instructed, to find a second solution y2(x). y'' + 36y = 0;    y1 = cos(6x) y2 = 2) The indicated function y1(x) is a solution of the given differential equation. Use reduction of order or formula (5) in Section 4.2, y2 = y1(x) e−∫P(x) dx y 2 1...

1. For each of these problems, (i) verify by direct substitution that y1 and y2 are...

1. For each of these problems, (i) verify by direct substitution that y1 and y2 are both solutions of the ODE, and (ii) find the particular solution in the form y(x) = c1y1(x) + c2y2(x) that satisfies the given initial conditions. (a) y''+5y'-6y=0, y1(x) = e^−6x , y2(x) = e^x , y(0)=2, y'(0)=1

The indicated function y1(x) is a solution of the given differential equation. Use reduction of order...

The indicated function y1(x) is a solution of the given differential equation. Use reduction of order or formula (5) in Section 4.2, y2 = y1(x) e−∫P(x) dx y 2 1 (x) dx        (5) as instructed, to find a second solution y2(x). y'' + 64y = 0;    y1 = cos(8x) y2 =

The indicated function y1(x) is a solution of the given differential equation. Use reduction of order...

The indicated function y1(x) is a solution of the given differential equation. Use reduction of order or formula (5) in Section 4.2, y2 = y1(x) e−∫P(x) dx y 2 1 (x)       dx (5) as instructed, to find a second solution y2(x). x2y'' -11xy' + 36y = 0; y1 = x6 y2 =

The joint density of Y1, Y2 is given by f(y) = k, −1 ≤ y1 ≤...

The joint density of Y1, Y2 is given by f(y) = k, −1 ≤ y1 ≤ 1, 0 ≤ y2 ≤ 1, y1 + y2 ≤ 1, y1 − y2 ≥ −1 0, otherwise a. Find the value of k that makes this a probability density function. b. Find the probabilities P(Y2 ≤ 1/2) and P(Y1 ≥ −1/2, Y2 ≤ 1/2). (Do you notice a relationship between them?)

use variation of parameters to find a particular solution y'' + y' +12y = xe2x y1...

use variation of parameters to find a particular solution y'' + y' +12y = xe2x y1 = e3x    y2 = e-2x