find the value of b for which the given equation is exact, and then solve it using that value of b
(xy^(2)+bx^(2)y)dx+(x+y)x^(2)dy=0
The given equation is "(xy^{2}+bx^{2}y)dx+(x+y)x^{2}dy=0".
Since the equation is exact we must have, "\\dfrac{\\partial M}{\\partial y} = \\dfrac{\\partial N}{\\partial x}".
Here "M = xy^{2}+bx^{2}y; N=x^{2}(x+y)"
Then, "2xy+bx^{2} = 3x^{2}+2xy \\implies b = 3"
Therefore, the given equation becomes "(xy^{2}+3x^{2}y)dx+(x+y)x^{2}dy=0", which can be written as
"\\begin{aligned}\n\\dfrac{dy}{dx} &= \\dfrac{xy^2+3x^2y}{x^2(x+y)}\\\\\n&=\\dfrac{xy(y+3x)}{x^2(x+y)}\\\\\n&=\\dfrac{y(y+3x)}{x(x+y)}\\\\\n\\end{aligned}"
This is a homogeneous equation. We use substitution to find the general solution.
Put "y=vx". Then "\\dfrac{dy}{dx} = v + x\\dfrac{dv}{dx}". Thus,
"\\begin{aligned}\nv+ x \\frac{dv}{dx} &= \\frac{vx(vx+3x)}{x(x+vx)}\\\\\n&= \\frac{v(v+3)}{(1+v)}\\\\\nx \\frac{dv}{dx} &= \\frac{v(v+3)}{(1+v)} - v\\\\\n&= \\frac{v^2+3v-v-v^2}{(1+v)} \\\\\nx \\frac{dv}{dx}&= \\frac{2v}{1+v} \\\\\n\\therefore \\Big(\\frac{1+v}{2v}\\Big)dv &= \\frac{dx}{x}\\\\\n\\frac{1}{2}\\frac{dv}{v} + \\frac{1}{2}dv &= \\frac{dx}{x}\\\\\n\\frac{dv}{v}+dv &= 2 \\frac{dx}{x}\\\\\n\\text{Integrating both sides,}\\\\\n\\log v + v &= 2\\log x + \\log c\\\\\n\\log v + v &= \\log cx^2\\\\\nv + \\log\\Big(\\frac{v}{cx^2}\\Big) &= 0\\\\\n\\log\\Big(\\frac{v}{cx^2}\\Big) &= -v\\\\\n\\frac{v}{cx^2} &= e^{-v}\\\\\n\\frac{y}{cx^3} &= e^{-\\frac{y}{x}}\\\\\nye^{\\frac{y}{x}}&=cx^3\n\\end{aligned}"
Comments
Leave a comment