The curve defined by the equation $\displaystyle y-e^{(xy)} + x=0$ has a vertical tangent at the point (1,0). To find this point, implicit differentiation is applied, leading to the expression for the derivative $y' = \dfrac{ye^{xy} - 1}{1 - xe^{xy}}$. The vertical tangent occurs when the denominator equals zero, specifically when $xe^{xy} = 1$. Substituting this condition back into the original equation confirms the point of tangency.
PREREQUISITESStudents and professionals in mathematics, particularly those studying calculus and differential equations, will benefit from this discussion. It is especially relevant for those interested in understanding the behavior of curves and their tangents.
Find where $y'$ is not defined. It is not where it is zero.grgrsanjay said:The curve $\displaystyle y-e^{(xy)} + x=0 $ has a vertical tangent at which point??
I started to differentiate it, then equating dy/dx to 0, then how should i proceed??
Differentiate implicitly: .$y' - e^{xy}(xy' + y) + 1 \;=\;0 \quad\Rightarrow\quad y' - xy'e^{xy} - ye^{xy} + 1 \;=\;0 $The curve .$\displaystyle y-e^{xy} + x=0 $ has a vertical tangent at which point?
soroban said:Hello, grgrsanjay!
I had an idea . . . then hit a wall.
Maybe someone can carry on ?
Differentiate implicitly: .$y' - e^{xy}(xy' + y) + 1 \;=\;0 \quad\Rightarrow\quad y' - xy'e^{xy} - ye^{xy} + 1 \;=\;0 $
. . . . . $ y' - xy'e^{xy} \;=\; ye^{xy} - 1 \quad\Rightarrow\quad y'(1-xe^{xy}) \;=\; ye^{xy}-1 $
. . . . . $y' \;=\;\dfrac{ye^{xy} - 1}{1 - xe^{xy}} $The curve has a vertical tangent where the denominator equals zero:
. . . $ 1 - xe^{xy} \:=\:0 \quad\Rightarrow\quad e^{xy} \:=\:\dfrac{1}{x} $Substitute into the original equation (?)
. . . $ y - \frac{1}{x} + x \:=\:0 \quad\Rightarrow\quad y \:=\:\dfrac{1-x^2}{x}$Does this help?