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Equation of the Tangent to a Parabola 📂Geometry

Equation of the Tangent to a Parabola

Derivation

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In the Case Where the Slope is Given

Let’s first look at the case where the slope is given.

When the equation of the line tangent to the parabola $y^{ 2 }=4px$ is $y=mx+n$, the two shapes must meet at only one point, thus $$ (mx+n)^{ 2 }=4px \implies m^{ 2 }x^{ 2 }+2(mn-2p)x+n^{ 2 }=0 $$ by the quadratic formula, $$ \frac { D }{ 4 }=m^{ 2 }n^{ 2 }-4mnp+4p^{ 2 }-m^{ 2 }n^{ 2 }=0 $$ simplifying this gives $n=\frac { p }{ m }$ and substituting this into the equation of the line, the equation of the line tangent to the parabola is found as follows. $$ y=mx+\frac { p }{ m } $$

In the Case Where a Point is Given

Next is the case where a point is given. However, the original rigorous proof is overly simplistic and not very helpful in the derivation, so we introduce a different derivation using differentiation, which is a bit loose.

The line $y=mx+\frac { p }{ m }$ is a tangent to the parabola $y^{ 2 }=4px$. Differentiating $y^{ 2 }=4px$ with respect to $x$ gives $2y\prime y=4p$. At point $(x_{ 1 },y_{ 1 })$ on the parabola, $y\prime =\frac { 2p }{ y_{ 1 } }$ $y\prime$ is equal to the slope of line $y=mx+\frac { p }{ m }$, hence $$ y=\frac { 2p }{ y_{ 1 } }x+\frac { y_{ 1 } }{ 2p }p $$ Multiplying both sides of the above equation by $y_{ 1 }$ gives $$ y_{ 1 }y=2px+\frac { y_{ 1 }^{ 2 } }{ 2 } $$ . Since point $(x_{ 1 },y_{ 1 })은$ is on the parabola, substituting $y_{ 1 }^{ 2 }=4px_{ 1 }$ into the above equation gives $$ y_{ 1 }y=2px+\frac { 4px_{ 1 } }{ 2 } $$ . Therefore, the equation of the tangent line passing through point $(x_{ 1 },y_{ 1 })$ is found as follows. $$ y_{ 1 }y=2p(x_{ 1 }+X) $$