" 5."ydy+xe^(x)cos^(2)ydx=0

Find the general solution of the differential equations e^(x)tan ydx+(1-e^(x))sec^(2)ydy=0

Solve :3e^(x)tan ydx+(1-e^(x))sec^(2)ydy=0

The solution of the differential equation 3e^(x)tan ydx+(1+e^(x))sec^(2)ydy=0 is

Solve the following differential equation: e^(x)tan ydx+(1-e^(x))sec^(2)ydy=0

Solve the following differential equation: 3e^(x)tan ydx+(2-e^(x))sec^(2)ydy=0, given that when x=0,y=(pi)/(4)

Find the particular solution of the differential equation e^(x)tan ydx+(2-e^(x))sec^(2)ydy=0 given that y=(pi)/(4) when x=0

2e^(x)dx-sec^(2)ydy=0

The equation of the curve satisfying the differential equation xe^(x)sin ydy-(x+1)e^(x) cos ydx=ydy and passing through the origin is

The equation of the curve satisfying the differential equation xe^(x)sin ydy-(x+1)e^(x) cos ydx=ydy and passing through the origin is

cos^(2)ydx-cosxdy=0